Current Topics in Membranes, Volume 42
Chloride Channels
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Current Topics in Membranes, Volume 42
Chloride Channels
Current Topics in Membranes, Volume 42 Series Editors Arnost KIeinzeller Department of Physiology University of Pennsylvania School of Medicine Philadelphia, Pennsylvania
Douglas M. Fambrough Department of Biology The Johns Hopkins University Baltimore, Maryland
Current Topics in Membranes, Volume 42
Chloride Channels Guest Editor William 8. Cuggino Departments of Physiology and Pediatrics The Johns Hopkins University School of Medicine Baltimore, Maryland
ACADEMIC PRESS San Diego
New York Boston London Sydney Tokyo Toronto
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Copyright 0 1994 by ACADEMIC PRESS, INC. A11 Rights Reserved. No part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopy, recording. or any information storage and retrieval system, without permission in writing from the publisher.
Academic Press, Inc. A Division of Harcourt Brace & Company 525 B Street, Suite 1900, San Diego, California 92101-4495 United Kingdom Edition pubfished by Academic Press Limited 24-28 Oval Road, London NW 1 7DX International Standard Serial Number:
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PRINTEDIN THE UNITED STATES OF AMERICA 94
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Contents Contributors ix Previous Volumes in Series xi
CHAPTER 1 Voltage-Dependent Chloride Channels in Plant Cells: Identification, Characterization, and Regulation of a Guard Cell Anion Channel Rainer Hedrich
Introduction 2 Ion Transport and Stornatal Movement 3 GCACl, a Voltage-Dependent Anion Channel 5 Gating Modifiers and Inhibitors 12 Diversity of Plant Anion Channels 19 Volume Regulation, Excitation, and Signal Transduction 23 VII. Outlook 27 References 30 I. 11. 111. 1V. V. VI.
CHAPTER 2 Molecular Biology of Voltage-Gated Chloride Channels Thomas J . Jentsch
I. 11. 111. IV.
Introduction 35 The ClC Family of CI- Channels 36 Channels or Channel Activators? 47 Summary and Outlook 50 References 52
CHAPTER 3 An IAA-Sensitive Vacuolar Chloride Channel Qais Al-Awqati
I. Introduction 59 11. The IAA-Sensitive Chloride Channel 62 References 7 1 V
Contents
vi
CHAPTER 4 Anion Channels in the Mitochondria1 Outer Membrane Marco Colombini
I. 11. 111. IV. V. VI.
Introduction 74 Basic Properties 75 Molecular Structure 77 Structure from Electron-Microscopic Imaging 84 The Voltage-Gating Process 90 The Properties of VDAC Can Be Tuned and Modulated 92 VII. Function 96 VIII. Prospects 97 References 97
CHAPTER 5 Regulation of Chloride Channels in Lymphocytes Michael D . Cahulan and Richard S . Lewis 1. Functions of T and B Lymphocytes
11. 111. IV. V.
103 Ion Channel Phenotype of Lymphocytes 104 Patch-Clamp Studies of Lymphocyte C1- Channels Functional Roles of CI- Channels 120 Summary and Prospects 123 References 124
108
CHAPTER 6 Chloride Channels in Skeletal Muscle and Cerebral Cortical Neurons Andrew L . BIatz
I. 11. 111. IV.
Introduction 131 Skeletal Muscle Chloride Channels 132 Non-Transmitter-Activated Neuronal CI Channels Summary 149 References 149
144
CHAPTER 7 The CFTR Chloride Channel Michael J . Welsh, Matthew P . Anderson, Devra P . Rich, Herbert A . Berger, and David N . Sheppard
I. Topology and Localization of CFTR 155 11. Localization of CFTR 155 111. Biophysical Properties of the CFTR C1- Channel
156
vii
Contents IV. Phosphorylation-Dependent Regulation of CFTR V. Nucleotide-Dependent Regulation of CFTR C 1 Channels 163 VI. Conclusion 166 References 166
160
CHAPTER 8 Chloride Conductances of Salt-Secreting
Epithelial Cells Raymond A . Frizzell and Andrew P . Morris I. 11. 111. IV. V.
Introduction 173 Secretagogue-Activated C1 Conductances 178 The Volume-Sensitive C1 Conductance: GV& 197 The Outward Rectifier 202 Summary 205 References 206
CHAPTER 9 GABAA Receptor-Activated Chloride Channels David R . Burt I. Introduction 216 11. Structure of GABA, Receptors 217 111. Function of GABA, Receptors 226
IV. V. VI. VII. VIII.
Actions of Drugs 231 Distribution of GABA Receptors 237 GABA Receptors and Disease 243 Comparison with Glycine Receptors 244 Future Prospects 245 References 246
CHAPTER 10 Chloride Channels along the Nephron Erik M . Schwiebert, Anibal G . Lopes, and William B . Guggino I. Introduction 265 11. Chloride Transport in Specialized Cells Associated with the Glomerulus 267 111. Chloride Transport in the Proximal Nephron: Proximal Convoluted Tubule through Thick Ascending Limb 274 IV. Chloride Transport in the Distal Nephron: Distal Convoluted Tubule through the Collecting Duct 282
Contents V. Chloride Transport in Cultured Cell Models of Renal Ion Transport 295 VI. Chloride Channels in Intracellular Compartments 297 VII. Renal Chloride Channel Biochemistry and Molecular Biology 299 VIII. Summary 304 References 305
CHAPTER 11 Chloride Ion Channels in Mammalian Heart Cells Tzyh-Chang Hwang and David C . Gadshy 1. Introduction and Overview 317 11. PKA-Regulated CI- Channels (CFTR) 319 111. Stretch-Activated C1- Channels 337
IV. Ca?+-Activated C1- Channels 338 V . Other C1- Channels 339 VI. Summary and Outlook 341 References 342
lndex 347
Contributors Numbers in parentheses indicate the pages on which the authors’ contributions begin.
Qais Al-Awqati (59), Departments of Medicine and Physiology, College of Physicians and Surgeons, Columbia University, New York, New York 10032 Matthew P. Anderson (153), Departments of Internal Medicine and Physiology and Biophysics, Howard Hughes Medical Institute, University of Iowa College of Medicine, Iowa City, Iowa 52242 Herbert A. Berger (153), Departments of Internal Medicine and Physiology and Biophysics, Howard Hughes Medical Institute, University of Iowa College of Medicine, Iowa City, Iowa 52242 Andrew L. Blatz (131), Department of Physiology, University of Texas Southwestern Medical Center at Dallas, Dallas, Texas 75235 David R. Burt (215), Department of Pharmacology and Experimental Therapeutics, University of Maryland School of Medicine, Baltimore, Maryland 21201 Michael D . Cahalan (103), Department of Physiology and Biophysics, University of California at Irvine, Irvine, California 92717 Marco Colombini (73), Laboratories of Cell Biology, Department of Zoology, University of Maryland, College Park, Maryland 20742 Raymond A. Frizzell (173), Department of Physiology and Biophysics, University of Alabama at Birmingham, Birmingham, Alabama 35294 David C. Gadsby (3 17), Laboratory of CardiadMembrane Physiology, The Rockefeller University, New York, New York 10021 William B. Guggino (265), Department of Physiology, The Johns Hopkins University School of Medicine, Baltimore, Maryland 2 1205 Rainer Hedrich (l), Institut fur Biophysik, Universitat Hannover, D304 19 Hannover 2 1, Germany
X
Contributors
Tzyh-Chang Hwang (317), Laboratory of CardiadMembrane Physiology, The Rockefeller University, New York, New York 1002 I Thomas J. Jentsch (33, Center for Molecular Neurobiology (ZMNH), Hamburg University, D-20246 Hamburg, Germany Richard S. Lewis (103), Department of Molecular and Cellular Physiology, Medical Center, Stanford University, Stanford, California 94035 Anibal G. Lopes (265), Instituto de Biofisica Carlos Chagas Filho, Universidade do Rio de Janeiro, Rio de Janeiro, RJ, Brazil Andrew P. Morris (173), Departments of Physiology and Cell Biology, and Gastroenterology, University of Texas Health Science Center at Houston, Houston, Texas 77030 Devra P. Rich (153), Departments of Internal Medicine and Physiology and Biophysics, Howard Hughes Medical Institute, University of Iowa College of Medicine, Iowa City, Iowa 52242 Erik M. Schwiebert (265), Department of Physiology, Johns Hopkins University School of Medicine, Baltimore, Maryland 2 I205 David N. Sheppard (153), Departments of Internal Medicine and Physiology and Biophysics, Howard Hughes Medical Institute, University of Iowa College of Medicine, 500 EMRB, Iowa City, Iowa 52242 Michael J. Welsh (153), Departments of Internal Medicine and Physiology and Biophysics, Howard Hughes Medical Institute, University of Iowa College of Medicine, Iowa City, Iowa 52242
Previous Volumes in Series Current Topics in Membranes and Transport Volume 19 Structure, Mechanism, and Function of the Na/K Pump* ( 1983) Edited by Joseph F. Hoffman and Bliss Forbush 111 Volume 20 Molecular Approaches to Epithelial Transport* (1984) Edited by James B. Wade and Simon A. Lewis Volume 21 Ion Channels: Molecular and Physiological Aspects (1984) Edited by Wilfred D. Stein Volume 22 The Squid Axon (1984) Edited by Peter F. Baker Volume 23 Genes and Membranes: Transport Proteins and Receptors* ( 1985) Edited by Edward A. Adelberg and Carolyn W. Slayman Volume 24 Membrane Protein Biosynthesis and Turnover (1985) Edited by Philip A. Knauf and John S. Cook Volume 25 Regulation of Calcium Transport across Muscle Membranes (1985) Edited by Adil E. Shamoo Volume 26 Na+-H+ Exchange, Intracellular pH, and Cell Function* ( 1986) Edited by Peter S. Aronson and Walter F. Boron Volume 27 The Role of Membranes in Cell Growth and Differentiation ( 1986) Edited by Lazaro J. Mandel and Dale J. Benos Volume 28 Potassium Transport: Physiology and Pathophysiology* ( 1987) Edited by Gerhard Giebisch * Part
of
the series from the Yale Department of Cellular and Molecular Physiology xi
xi
Previous Volumes in Series
Volume 29 Membrane Structure and Function ( 1987) Edited by Richard D. Klausner, Christoph Kempf, and Jos van Renswoude Volume 30 Cell Volume Control: Fundamental and Comparative Aspects in Animal Cells (1987) Edited by R. Gilles, Amost Kleinzeller, and L. Bolis Volume 31 Molecular Neurobiology: Endocrine Approaches ( 1987) Edited by Jerome F. Strauss, 111 and Donald W. Pfaff Volume 32 Membrane Fusion in Fertilization, Cellular Transport, and Viral Infection (1988) Edited by Nejat Diizgunes and Felix Bronner Volume 33 Molecular Biology of Ionic Channels* (1988) Edited by William S. Agnew, Toni Claudio, and Frederick J. Sigworth Volume 34 Cellular and Molecular Biology of Sodium Transport* (1989) Edited by Stanley G. Schultz Volume 35 Mechanisms of Leukocyte Activation (1990) Edited by Sergio Grinstein and Ori D. Rotstein Volume 36 Protein-Membrane Interactions* (1990) Edited by Toni Claudio Volume 37 Channels and Noise in Epithelial Tissues (1990) Edited by Sandy I. Helman and Willy Van Driessche
Current Topics in Membranes Volume 38 Ordering the Membrane Cytoskeleton Tri-Layer* (1991) Edited by Mark S. Mooseker and Jon S. Morrow Volume 39 Developmental Biology of Membrane Transport Systems (1991) Edited by Dale J. Benos Volume 40 Cell Lipids (1994) Edited by Dick Hoekstra Volume 41 Cell Biology and Membrane Transport Processes* (1994) Edited by Michael Caplan
CHAPTER 1
Voltage-Dependent Chloride Channels in Plant Cells: Identification, Characterization, a n d Regulation of a Guard Cell Anion Channel Rainer Hedrich Institut fur Biophysik. Universitat Hannover. D-30419Hannover 21. Germany
I. Introduction 11. Ion Transport and Stomata1 Movement Ill. GCACI, a Voltage-Dependent Anion Channel A. Identification B. Selectivity C . Single-Channel Conductance Depends on Extracellular Anions D. Voltage Dependence and Kinetics E. Calcium and Nucleotides F. Identification of the Putative Channel Protein IV. Gating Modifiers and Inhibitors A. Growth Hormones B. Malate C. Anion Channel Blockers V. Diversity of Plant Anion Channels A. Anion Channels in Higher Plants and Algae B. Different Anion Channels or Different Modes of GCACI? VI. Volume Regulation, Excitation, and Signal Transduction A. Downregulation of Volume and Turgor B. Do Voltage Dependence and Kinetics of the GCACl Ask for Excitability? C. How Do Plant Hormones Work? VII. Outlook References Currenr Topics in Membranes, Volume 42 Copyright 0 1 9 4 by Academic Press. Inc. All rights of reproduction in any form reserved.
1
Rainer Hedrich
2 1. INTRODUCTION
Since the early voltage-clamp experiments from Cole and Curtis (1938,1939) on giant algal cells, excitability has been recognized in membranes of animals and plants. The action potential in the plasma membrane of these algal cells, which were often called “green muscles,” is generated by conductance changes with respect to calcium, chloride, and potassium ions (for review, see Tazawa et id., 1987). From voltage-clamp studies we have now learned that this action potential is initiated by calcium ions entering the cytoplasm followed by an activation of a Ca’+-dependent anion conductance which depolarizes the membrane.’ This depolarization in turn induces a potassium efflux. Thus depolarization through calcium influx and chloride efflux is followed by a potassium-dependent repolarization phase. Even though these transient potential changes were detected simultaneously to those of the squid giant axon the function of the algal action potential is not yet fully understood, and a complete picture of the ion channels mediating the observed conductance changes is still missing. In order to provide a basis for comparison to animal counterparts within the frame of this issue I focus on ion channels of higher plant cells which have been approached at the molecular level by patch-clamp studies (for review, see Hedrich and Schroeder, 1989; Blatt, 1991; Tyerman, 1992) and by cloning of the related proteins (see Section VII, Outlook; Anderson et al., 1992; Sentenac et al., 1992). In contrast to giant algal cells which allowed the application of conventional voltage-clamp and internal perfusion techniques, the elucidation of ion channels in smaller plant cells had to await the development of the patch-clamp technique (Neher and Sakmann, 1976; Hamill et al., 1981; Schroeder et al., 1984; Hedrich et al., 1986). As in animal cells “the major biophysical advances of the last decade have depended heavily on the ability to isolate single sensory cells-often by using enzymes-and to patch clamp them” (Hille, 1992). The combined use of the patch-clamp technique and the development of new methods to isolate wall-free cells (protoplasts), which essentially were based on the availability of improved enzyme preparations, enabled direct studies on ion channels embedded in the plasma membrane, the vacuolar membrane, and the photosynthetic membrane (Hedrich and Neher, 1987; Schonknecht et al., 1988; Hedrich and Schroeder, 1989).2
’
Please note that anion gradients in plant cells are inverse when compared to animal cells (see Section 1II.B). For techniques to isolate vacuoles or inflate the stacked membrane continuum of thylakoids, see Keller and Hedrich (1992).
3
I . Voltage-Dependent Chloride Channels
Even though the presence of ion channels has been shown in many plant cell types, I concentrate on plasma membrane ion transport in a specialized cell type, the guard cell, for three reasons: (i) they control the water status of the plant (for review see Raschke, 1979), (ii) isolated protoplasts of this cell type maintain their physiological function (see below and Zeiger and Hepler, 1977; Schnabl, 1981; Assmann et ul., 1985; Serrano et al., 1988; Marten et ul., 19911, and (iii) since the first detection of potassium-selective channels, guard cells have become one of the electrophysiologically best-characterized cell type providing a broad background on the physiology and biophysics of ion channels and ion pumps in general (for review, see Schroeder and Hedrich, 1989; Blatt, 1991). In the detailed presentation of a highly regulated guard cell union channel (GCACl) I , however, compare its properties to anion channels from other plant cells and giant algae (for comparison to animal counterparts, see also Hedrich and Jeromin, 1992).
II. ION TRANSPORT AND STOMATAL MOVEMENT
Terrestrial plants exchange carbon dioxide and water with the atmosphere through turgor-operated cellular valves, the stomata, located in the outer epidermis of leaves and stems. Light, CO,, and plant hormones have been shown to affect the stomatal aperture between the two poreforming guard cells (Figs. 1 and 2, see also Raschke, 1979; Marten et al., 1991).
Light
C02
Ca2+
pH
-
Hormones
A Volume / Turgor
FIGURE 1 Control of stomatal aperture. External signals such as changes in light intensity; COz, CaZt, and H + concentration; or the hormone level result in changes in the salt content of guard cells and finally their volume and turgor.
Rainer Hedrich
4 2c
15
h
E
1
v
2
1c
3
Y
L
aJ
Q
U
5
I
C
I
I
120
I
I
3 I
240
Time (min) 2oc
B
-
$
15C
?
3
c L
E 1oc
Q
\*
10
FIGURE 2 (A) Stomata1 opening of broad bean epidermal strips in response to auxins (I-NAA, 2, 4-D), light. and the fungal toxin fusicoccin (FC) (Marten ct a / . , 1991. reprinted Concentrawith permission from Narure, copyright 1991 Macmillan Magazines Limited). (9) tion dependence of auxin-induced stornatal opening (Lohse and Hedrich. 1992. with permission).
1. Voltage-Dependent Chloride Channels
5
At the beginning of the century it was already possible to correlate stomatal aperture to the potassium content of the guard cells (Imamura, 1943). Microprobe analyses later unequivocally demonstrated that the potassium salts, KCI and K2 malate, accumulate in guard cells during stornatal opening (Humble and Raschke, 1971). Thus the increase in turgor and volume in a pair ofguard cells, expressed through the characteristic structure of their cell wall, inflates the cell bodies along their axes to form a diffusion pore between them (Raschke, 1979). During stornatal closure potassium salts are released again and the stornatal pore closes. The basic function of guard cell ion transport is to initiate signal transduction pathways on the one hand (Assmann et ul., 1985; Serrano et al., 1988; Schroeder and Hagiwara, 1990a; Marten rt [ i l . , 1991) and to regulate a net flow of ions and establish an electrical driving force that promotes the movement of other ionsisolutes on the other (Hedrich and Schroeder, 1989). Patch-clamp and conventional microelectrode measurements have demonstrated that inward- and outward-rectifying potassium channels represent the predominant potassium conductances in the plasma membrane of guard cells and higher plants in general (Fig. 3; Hedrich and Schroeder, 1989; Schroeder and Hedrich, 1989;for review, see Blatt, 19911. Activated by hyperpolarization and depolarization, these voltage-dependent potassium channels control potassium fluxes during stornatal movement. The resting potential can be decomposed into a K + conductance ( E K + = - 120 m V ) achieved by the activity of inward-rectifying K + channels and an outward-directed H + ATPase pumping the membrane potential to -200 m V [or even more negative values (Fig. 4) see also Blatt, 1991; Lohse and Hedrich, 19921. Apart from the resting level, sustained and transient depolarizations, called “action potentials,” have been reported in guard cells and attributed to either stomatal closure or the transduction of external and internal signals (Thiel e f al., 1992). In the following I further restrict myself to describing the major role of a voltage-dependent anion channel (GCACI) in the control of salt release, excitability, and the transduction of extracellular and intracellular signals.
111. GCAC 1, A VOLTAGE-DEPENDENTANION CHANNEL
In order to study plasma membrane anion fluxes the patch-clamp technique was applied to guard cell protoplasts (Schroeder et d.,1984; Raschke and Hedrich, 1990). Patch pipettes were sealed onto protoplasts isolated enzymatically from the epidermis of broad bean (Vica.faba)leaves
6
Rainer Hedrich
d -
-100 o 100 FIGURE 3 (A) Schematic diagram summarizing the ion channels found to date in the plasma membrane of guard cells (modified from Cosgrove and Hedrich, 1991, with permission). ( B ) T w o types of voltage-dependent potassium channels in the plasma membrane of guard cells (current trace and O ) ,barley aleuron cells (0). and cells from a tobacco tumor cell line (A).Inward- and outward-rectifying whole-cell K currents following elicitation by a voltage ramp from -200 to 120 mV (R. Hedrich, unpublished).
-200
+
(Raschke and Hedrich, 1990). Current and voltage recordings were performed in the whole-cell configuration and cell-free membrane patches.
A. Identification In our initial investigations anion-selective channels appeared around the reversal potential of the potassium ion (- 100 to -40 mV). Since these currents were small (25-50 PA) and the membrane resistance was high (> 10 GR), fluctuations of single anion channels could be resolved even in the whole-cell configuration. When the membrane voltage was depolarized
1. Voltage-Dependent Chloride Channels
7
A
'5 Im
l6mV
-150mV
-150mV
FIGURE 4 Electrogenic proton pumping hyperpolarizes the plasma membrane of guard cells. ( A )Time course of whole-cell current and voltage generated by the outward-directed H '-ATPase of the plasma membrane. ( B ) Current-voltage relation of the Ht-ATPase. (Lohse and Hedrich. 1992, with permission.)
beyond the potassium equilibrium potential, anion- and K -release channels could be recorded simultaneously (Keller er al., 1989). After replacement of potassium by the K + channel blockers Cs+ or TEA' (tetraethylammonium) or impermeable NMG+ (N-methylglucamine), K + channels were absent whereas anion channel activity was basically unchanged. In the presence of, e.g., 150 mMCsCl on the cytoplasmic side of the membrane and 30 m M CsCl in the bath, single 38-pS channels reversed direction close to Ec,-, indicating a higher permeability of this channel toward chloride than to potassium (Keller er al., 1989). +
B. Selectivity In order to characterize the selectivity filter of the anion channel, patchclamp experiments were performed with solutions containing salts of nonpermeating cations in combination with permeant anions. When chloride in the extracellular solution was substituted by other halides as well as by the physiologically relevant anions, malate, and nitrate, the current reversal potential of GCACl was shifted in a way expected for an anion
8
Rainer Hedrich
channel with a permeation path different from water (Robinson and Stokes, 1959). Our studies revealed a permeability sequence relative to chloride (Hedrich and Marten, 1993) of
NO,4.2
2
I- > Br- > C1- > > malate?3.9 1.9 1 0.1.
This sequence resembles the Eisenman Series I, indicating “weak” electrostatic interaction(s) of anions with cationic binding site(s) where the change in free energy upon binding of the ion is mostly determined by the dehydration energy (Eisenman and Horn, 1983). When, on the other hand, chloride was replaced by glutamate or gluconate, anion currents were absent. Experiments using organic anions with molecule radii between those of malate and glutamate/gluconate will thus allow the determination of whether the pore in GCACl is in the same order of magnitude as that found for animal anion channels (3-5 A; see Bormann er al., 1987). C. Single-Channel Conductance Depends on ExtracellularAnions
The ionic composition of the extracellular milieu, the cell-wall space, is tissue dependent and varies from almost distilled water up to 50-60 mosmol potassium salts (Speer and Kaiser, 1991). The anion content of the medium around guard cells is dominated by chloride and malate which shuttle across the plasma membrane during stornatal movement (for review, see Raschke, 1979). Thus the cell-wall space of open stomata should be low in anions but should continuously increase during closure when the guard cells release a major fraction of their ionic content (from 500-800 to 100-200 mM; Raschke, 1979). Even though reaccumulation of K + salts by the mesophyll and/or neighboring cells may take place, the anion concentration changes manyfold. Patch-clamp studies have revealed that the peak amplitude of anion currents increases as the extracellular chloride concentration is raised from 0 up to 300 mM. This reflects an inverse dependence of GCACl on the chloride gradient across the plasma membrane. In addition to wholecell recordings it could be documented through single-channel experiments that the rise in the macroscopic current results from an increased singlechannel conductance (Fig. 5 , Hedrich and Marten, 1993). The chloride sensitivity of GCACl lies within the physiological range of the external anion content (Bowling, 1987; Speer and Kaiser, 1991). This behavior is reminiscent of the dependence of the K + channel RCK4, a shaker K + channel subtype from rat brain, on external potassium (Pardo et al., 1992). In contrast to GCACl, extracellular ions increase
9
1. Voltage-Dependent Chloride Channels 84mM CL-
6mM Cl-
0 mM Cl-
-80rnV
-100 rnV
1OWI
2OOms
FIGURE 5 The single-channel conductance of GCAC I reflects the extracellular chloride concentration. Decrease in chloride concentration suppresses anion release through the anion channel (Hedrich and Marten, 1993, with permission of Oxford University Press).
the mean open time or gating charge displacement of RCK4 rather than its single channel conductance. Whereas the role of a regulatory, extracelM a r ion binding site(s) in RCK4 expressing nerve cells is still unknown, one might suppose that the inverse relationship of the GCACl singlechannel amplitude to the anion gradient allows anion efflux to occur and thus stomata1 closure to proceed even at increasing extracellular anion levels.
D. Voltage Dependence and Kinetics Current-voltage curve analysis of whole-cell ion fluxes has revealed that outward chloride fluxes are activated near -100 mV and peak at -30 to -40 mV. Chloride currents decline through the decrease in the electrochemical driving force when the membrane potential is stepped to values more depolarized than -30 mV, reversing direction at the Nernst potential for chloride (Fig. 6 and Hedrich et al., 1990). Activation kinetics of the anion channel have usually been determined by a series of voltage pulses where the membrane potential is clamped to the resting potential of the cell (negative to - 100 mV; Hedrich et al., 1990; Lohse and Hedrich, 1992). Upon stepping the voltage to values between -70 and - 10 mV, currents activate with a half-time between 30
10
Rainer Hedrich
-200
Activation
-100
Deactivation
0
lnactivation -LO
-160mV
-30 100 ms
FIGURE 6 Voltage-and time-dependent activity of anion channels recorded in whole cells and outside-out patches. Current-voltage relation of whole-cell anion currents during a voltage ramp from -200 to 60 mV (upper traces). Closed times (T,) of single anion channels (insets) recorded at voltages indicated. Anion currents generated by voltage pulses from a holding potential of - 160 to - 100, -70. -50, -30. and - 10 mV each followed by a pulse to + 15 mV (activation). Tail current resulting from a pulse to -30 mV followed by a pulse to - 160 mV (deactivation). lnactivation resulted from prolonged voltage stimulation. (Hedrich ef a/., 1990, with permission of Oxford University Press).
and 10 msec. During subsequent repolarization to the resting potential, large tail currents correspond to the instantaneous rise in the electrical driving force for anion efflux and the complete deactivation of GCACl takes place in less than 20 msec. Analysis of the single-channel activity under steady-state conditions have revealed that “deactivation” results from an increase in the mean closed-time of the anion channel with hyperpolarizing potentials. During prolonged depolarization anion channels inactivate in a voltagedependent manner (Hedrich et al., 1990; Marten et a / . ,1992, 1993). Inacti-
1. Voltage-Dependent Chloride Channels
11
vation is slow (half time I0-12sec) with respect to the inactivation of animal Na', K', and Ca?' channels and activation kinetics of GCACl . 3 Anion channel activity could be restored from inactivation during repolarization. Using the same experimental system and voltage protocol the kinetics of voltage-dependent activation and de- and inactivation of GCAC 1 (Hedrich rr d . , 1990) have been confirmed by Schroeder and Keller ( 1992).4 E. Calcium and Nucleotides
Anion currents in the presence of MgATP an 0.1-1 mM of the calcium buffer EGTA and in the absence of exogenous calcium in the cytoplasm (pipette solution) and 0.1 m M calcium in the extraceflular medium did not exceed the background level until the external Ca'+ concentration was raised to 2 10 mM (Hedrich er ol., 1990). Upon increasing Ca" the current amplitude increased 5- to 20-fold. External Ca'+ failed, however, in activating GCACl when (i) cytoplasmic Ca" was buffered to nanomolar concentrations using 10 m M EGTA or (ii) MgATP was excluded from the pipette solution and ATP scavengers were present. These experiments documented the requirement of Ca'+ and MgATP for channel activation. Since Ca'+- and nucleotide-dependent activation peaked 1-2 min after the whole-cell configuration was established, phosphorylation of the anion channel or regulator(s) may account for the delay. However, apart from MgATP (2-10 mM), ATPys and GTPys at 100 p M , in the absence of ATP scavengers, were able to support &'+-dependent activation. Thus it is unclear whether low levels of endogenous ATP suffice for phosphorylation or whether channel activation requires only the binding of nucleotides. As mentioned in the Introduction, voltage-clamp experiments on giant algal cells have shown that a Ca2+-and ATP-modulated anion conductance is involved in the action potential (Lunevsky er d., 1983). A more detailed comparison to GCACl has, however, to wait until the single-channel equivalent(s) of the anion conductance is (are) identified.'
' It should be noted that the whole-cell anion currents did not decay completely but to a background level (25-50 pA) representing less than 20% of the current (Keller et n l . . 1989: see also below). Their GCACl was named r-type for rapid activating current. ' Promising first attempts to answer this question through microdissection of the cell wall and attachment of patch pipettes have been made (Laver, 1991). Subsequent studies using intracellular perfusion or cell-free membrane patches might thus give new insights into the regulation of these channels by cytoplasmic factors.
12
Rainer Hedrich
F. Identification of the Putative Channel Protein
In a survey of compounds capable of interacting with the anion channel we have selected IAA-94 and IAA-23 in order to test their suitability as potential ligands for the isolation of the channel protein. We have selected these two compounds in particular since they have already been successfully employed in the isolation of anion channels from kidney epithelia (Landry ef d., 1989; Redhead et a / . , 1992; see also Chapter 3, by Q. AlAwqat i) . IAA-23, a structural analogue of IAA-94, was used to enrich ligandbinding polypeptides from the plasma membrane of guard cells. From this protein fraction a 60-kDa polypeptide cross-reacted specifically with polyclonal antibodies raised against anion channels isolated from kidney membranes. In contrast to guard cells, mesophyll plasma membranes were deficient in voltage-dependent anion channels and lacked cross-reactivity with the antibody (Marten et al., 1992). When membrane fractions, other than plasma membranes, were analyzed immunologically cross-reactions with other polypeptides were observed as well. Whether this represents anion-permeable channels in vacuolar, photosynthetic, or mitochondria1 membranes (for review, see Hedrich and Schroeder, 1989; Keller and Hedrich, 1992) needs further investigation. IV. GATING MODIFIERS AND INHIBITORS A. Growth Hormones
The opening of the stomatal aperture is elicited when guard cells are exposed to the growth hormones auxins (see Fig. 2A). Dose-response curves for auxins show an optimum around 5 x low6M , followed by a decay at higher concentrations (see Fig. 2B; Marten et ai., 1991; Lohse and Hedrich, 1992). This indicates that guard cells possess recognition sites for auxins as well as mechanisms for translating the hormonal signal into ion fluxes which, in turn, cause volume increase and stomatal opening. The early events in auxin signaling were characterized by patch-clamp studies on the hormone interaction with channels of guard cell protoplasts isolated from auxin-responsive epidermal layers. When auxins were applied to the external solution the activation potential and current amplitudes were altered in a dose-dependent manner. A comparison of the whole-cell currents and the single-channel activity (NsP,) in excised membrane patches (Fig. 7 ) demonstrated that macroscopic anion fluxes
13
I . Voltage-Dependent Chloride Channels
A
I
B
Potential (mV) FIGURE 7 Modutation of the activation potential of GCACl by auxin. Comparison of whole-cell anion currents and single-channel activity (A) before ( I ) and after auxin stimulation (11). Single-channel activity ( B ) is expressed by the number ( N ) of single channels in the cell-free membrane patch and their open probability (Po). (Marten el a!., 1991, reprinted from Nature. copyright 1991 Macmillan Magazines Limited.)
were generated by auxin-sensitive anion channels. The slope of the current-voltage curve results from a shift in the threshold potential of activation toward more negative voltages superimposed by a voltagedependent block (Marten et al., 1991,1993). The specificity of the auxin interaction with GCAC 1 is further characterized by: reversibility of channel modulation upon removal of auxins from the medium; side-specific recognition site(s) for auxins located only at the external face of the channel; no requirement of cytoplasmic factors for hormone targeting through the anion channel; discrimination against other phytohormones; channel-specific interaction since the inward-rectifying K channel is not affected. +
14
Rainer Hedrich
Furthermore, preliminary experiments have shown that the level of expression of a putative auxin receptor (Palme, 1991)in transgenic tobacco alters the dose dependence of the auxin-induced stomatal opening (G. Lohse and R. Hedrich, unpublished) and that voltage-dependent anion currents exist in cells of an auxin autotroph tobacco culture (Fig. 8. P. Dietrich and R. Hedrich, unpublished).6 In the absence of auxin the voltage gate of these cells is located at more hyperpolarized potentials compared to guard cells, reminiscent of GCAC I in the presence of high hormone levels. Future studies will show whether “receptor” channel density or the location of its voltage gate is crucial for hormone sensitivity. 8. Malate Is malate a possible CO, sensor: how do guard cells sense the intercellular CO, concentration? Stomata close upon an increase in intercellular CO,, one of the conditions reflecting the inability of the photosynthetic apparatus to take advantage of excess CO,. Low CO, levels, on the other hand, cause stomatal opening (for review, see Raschke, 1979). Sudden changes in CO, concentration and light intensity cause oscillations in stomatal aperture, a feedback mechanism which might involve activation-inactivation cycles of GCAC 1. Photosynthetic subtypes are characterized by the pattern of their assimilation products, where malate content, transport, and its cellular and subcellular compartmentation reflect the metabolic level of different cell types.’ When the extracellular side of the plasma membrane is exposed to malate the amplitude of whole-cell anion currents increases while the voltage gate shifts toward hyperpolarized potentials (Fig. 9A), a behavior we have already recognized during auxin action (see Fig. 7: Marten et al., 1991). The half-saturation constant for malate action was 0.4 mM, a concentration which is well within the physiological range of this dicarboxylate (Speer and Kaiser, 1991). Malate levels above 1 mM shifted the voltage gate by almost -80 mV (Hedrich and Marten, 1993). The increase in current amplitude in the presence of this extracellular effector is a consequence of channel openings at a voltage range of higher Similar observations on another tobacco cell line have also been reported at the 9th International Workshop on Plant Membrane Transport by Barbier-Brygoo. 1992. One exception are the Crassulaceae (CAM plants) to which most of the desert plants belong and where stomata open at night. but close during the day, opposite to the other plant types.
’
15
I . Voltage-Dependent Chloride Channels
U (mVI I
0-
.-...
-100 I
I
-LO
'
I
/-
I
/ /'
-
-50
-
'0
N.tabacum
CO
V. faba --I50
driving force for anion release. On the single-channel level malate causes a shift in voltage dependence rather than a change in unit conductance (cf. Section II1,C.). External malate released from the photosynthetic tissue, neighboring cells, or guard cells during stomata1 closure, therefore, causes the following chain of events (cf. Fig. 13B): (i) a shift of the voltage gate of GCACl toward the resting potential; (ii) induction of anion release, a fraction of which is malate (Van Kirk and Raschke, 1978); (iii) elevated malate levels in turn feedforward anion release. After inactivation to the background conductance (Fig. 9B, R. Hedrich and I. Marten, 1993) release of anions proceeds until malate dissociates from GCACl and the binding site is occupied by excess chloride (cf. Section III,C.), which in turn causes resetting of the voltage gate. Therefore malate-sensitive anion channels may provide a mechanism whereby stomata adapt to the current photosynthetic capacity of the leaf. Upon changes in the environmental conditions cross-talk between guard cells and the photosynthetic tissue should enable the control of COzuptake and water loss. C. Anion Channel Blockers
When anion channel inhibitors are applied to the bathing solution both the voltage dependence and current amplitude are altered. The shift and block of the anion channel saturate as a function of the effector concentra-
Rainer Hedrich
16
b
1-5
time Is1
FIGURE 9 Modulation of the plasma membrane anion channel of guard cells by malate. ( A ) Malate-induced shift in the activation potential and peak anion fluxes. Current-voltage relation of whole-cell anion currents before (a) and during (b) bath perfusion with malate resulting from voltage ramp stimulation. (B) Transient activation of GCAC I following malate application. Time course of malate-induced whole-cell anion currents in guard cells clamped to -YO mV. Anion currents of a single guard cell (inset) and malate-induced ion fluxes of three different cells normalized with respect to the peak current. (Hedrich and Marten, 1993, with permission).
I . Voltage-Dependent Chloride Channels
17
tion. However, the shape of the curve and thus the kind of interaction with a putative “binding site” differs strongly (Marten et d.,1993). Whereas the channel block can be explained by an interaction of the ligand with the open mouth of the channel, the “gate-shifting’’ action may result from adsorption of the ligand(s) at sites which directly or indirectly alter the intramembraneous electrical field (cf. Armstrong and Cota. I991 1. The effects on GCACI elicited by anion channel blockers are characterized by reversibility of modulation when effectors are removed from the extracellular medium,8 and side specificity since cytoplasmic inhibitor levels up to 100 p M are not effective. The sensitivity of the channel to inhibitors’ is expressed by the sequence of the inhibitor constants (Kd in micromolars, Marten et al., 1992,1993): PA (>loo) < A-9-C (100) < NA (20) < IAA-94 (7) < NPPB (4) = SITS (4) < DNDS (0.5) < DIDS (0.2). Interaction with the inhibitor (Fig. 10, right panel) is characterized by a flickering block (Gogelein, 1988). Whereas DIDS only affected ion permeation inhibition by e.g., SITS and DNDS was superimposed with a shift in the voltage gate.“’ As expected from voltage (depo1arization)dependent blockers the decay times of the anion current are strongly reduced at positive potentials (Fig. 11; Marten, 1993; Marten (’I nl., 1993). In sections IV, A-C 1 have shown that extracellular growth hormones, the key metabolite malate, and anion channel blockers are able to alter the voltage sensor (Marten et al., 1991,1993; Hedrich and Marten, 1993). All gating modifiers studied so far were anionic under our experimental conditions. It is thus tempting to speculate that the nature of the ligand occupying an “anion binding site” at the external face of GCAC 1 controls the location of the voltage gate. On the other hand residues such as aryl, alkyl, or sulfonyl groups may determine whether and how the compound occludes the channel pore.
*
Prolonged exposure of guard cells to NPPB and DIDS irreversibly increased the leak conductance. PA = p(dipropylaminosulfony1) benzoic acid; A-9-C = anthracene-9-carboxylic acid: IAA-94 = “6.7acid: NA = 2-~a.a.a-trifluoro-m-toluidino)-pyridine-3-carboxylic dichloro-2-cyclopentyl-2.3-dihydro-2-methylI -oxo- IH-inden-5-yl)oxy]acetic acid: NPPB = 5 = nitro-2-(3-phenylpropylarnino)benzoic acid; SITS = 4-acetamido-4-isothiocyanostilbene2,2‘-disulfonic acid: DNDS = 4,4’-dinitrostilbene-2.2’-disulfonic acid: DIDS = 4,4‘-diisothiocyanostilbene-2,2‘-disulfonic acid. The possibility that DIDS shifts the voltage sensor out of the potential range tolerated by guard cell protoplasts cannot be excluded.
“’
lOOpM SITS
control
-30 rnV
-6OrnV
-65 rnV
-80 mV
-85 mV
-100 rnV S
I
1-
P
A
I
r-q+-"
-100 m V
I
lOOms
FIGURE 10 Modulation of the single-channel properties of GCAC 1 by the stilbene derivative SITS. Single-channel activity recorded from a cell-free membrane patch in the absence (left) and presence of SITS (right). (Hedrich er a/..1990. with permission).
I . Voltage-Dependent Chloride Channels
19
500pA
50ms
FIGURE 11 Voltage-dependent block of the anion current by the stilbene derivative SITS Depolarization-( +56 mV) induced anion currents in the absence (a) and presence (b) of 10 p M SITS. Repolarization to -204 mV causes tail currents (framed and enlarged on the left). Note that tail currents i n the presence of SITS could be induced by repolarization after a prepulse where currents were absent. The increase of the tail current represents unblock (Marten cf a / . , 1993, with permission).
V. DIVERSITY OF PLANT ANION CHANNELS
A. Anion Channels in Higher Plants and Algae
Anion channels comprise the most diverse class of ion channels in animal cells, with respect to both the single-channel conductance and their regulation (Frizzell and Halm, 1991; Greger, 1992; and chapters of this issue). Table I summarizes related features of plant and algal anion channels.]' The conductance spectrum ranges from 1 to 200 pS. Here, three conductance levels can be distinguished: 1-pS channels, which could only be detected by noise analysis (Schroeder and Keller, 1992); 20- to SO-pS channels, e.g., GCACl; and large conductance anion channels. With respect to their voltage dependence, anion channels fall into two major classes at least: inward- and outward-rectifiers. A third class is activated mechanically by stretching the membrane (for animal counterI ' For the sake of comparison studies which lack single-channel or noise analysis have not been included.
TABLE I Comparison of the Basic Characteristics of Plant and Algal Anion Channels" Membrane Conductance (pS) Plant Suspension cells Asclepias ruberosa Suspension cells Amaranthus tricolor Suspension cells Daucus carota Suspension cells Nicotiana tabacum Roots Triticum aestivum
Selectivity
PM
100
CI- > K +
PM
200
NO;
PM
15
PM
100
PM
4
NO,-
> CI- > K - > ASP-
2
Activation
Reference(s)
Hyperpolarization
Schauf and Wilson (1987)
Hyperpolarization Depolarization
Zimmermann ( p e n comm.)
Hyperpolarization ATP
Barbara
CI > I - > > PO4' .C104
PI
rrl. ( 1994)
Skerrett and Tyerman (1994)
Triricum turgidum Mesophyll cells Peperomia metallica Cotyledons
TM
65-150
PM
5-40
NO3- > CI
Depolarization
Schonknecht
Voltage independent
Lew (1991)
('I01.
(1988)
22
Rainer Hedrich
parts, see Sachs, 1986; Morris, 1990). The role of Ca2+and nucleotides is unclear or has not been studied in cells other than guard cells (see Section IV); a detailed inhibitor analysis is not yet available.'* B. DifferentAnion Channels or DifferentM o d e s of GCACI? Just before Keller el al. (1989) identified GCACl , I 3 Schroeder and Hagiwara (1989) detected an anion conductance in whole cells with a voltage dependence, Ca*+ activation, and kinetics remarkably different from those of GCACl . Ionic currents were elicited by membrane polarization only when cytoplasmic Ca*+ was buffered to or above 1.5 p M , with the membrane clamped to a depolarized potential ( + 40 mV) close to the anion equilibrium. These currents activated almost instantaneously and did not deactivate (when compared to those in Fig. 6), during 1 sec pulses to potentials negative and positive of +40 mV indicating that channels activate fast (Schroeder and Hagiwara, 1989) or were already open at the holding potential. The instantaneous current-voltage curve revealed an almost ohmic behavior whereas in the steady-state anion fluxes were supposed to exhibit the same current-voltage relation as GCACl (Schroeder and Hagiwara, 1990b). However, in recent experiments of Schroeder and Keller (1992), where cytoplasmic Ca2+ was buffered to 150 nM and the membrane held at -100 mV, anion currents could be elicited by extremely long pulses to depolarized potentials as well. Under these conditions anion currents activated very slowly. Since 10 sec voltage steps did not create steadystate currents a 15-min ramp from +40 to -100 mV was used to obtain a quasi-steady-state current-voltage curve. In contrast to the steady-state current-voltage curve of anion currents in high cytoplasmic calcium which was identical to GCACl-like currents the current-voltage curve derived from a 15 min ramp revealed (i) a less steep voltage dependence, (ii) a peak current at a potential of about 0 rnV (-30 to -40 mV for GCACI), (iii)only partial deactivation at hyperpolarized potentials, and (iv) a unitary conductance of about 1 pS (30-40 pS for GCACI). In order to distinguish this slow-activating current from GCACl, which was often superimposed on recordings, GCACI was named r-type (r for rapid) and the former Ca2+-dependent type (Schroeder and Hagiwara, 1989) was named s-type (s for slow; Schroeder and Keller, 1992). I? In contrast to Keller er a/. (1989). studies by Marten ef a / . (1993) did not observe a Zn2+ block on GCACl. l 3 At that time, the voltage-dependent anion channel was not yet named GCAC1. This terminology was introduced by Hedrich and Jeromin (1992) and Marten et a/. (1992).
1 . Voltage-DependentChloride Channels
23
Linder and Raschke (1992), have also studied the slow-activating anion conductances in guard cells of broad bean and Xanthium strumarium (here called slow anion channel, SLAC) and have shown s-type-like kinetics. However, the single-channel conductance (33 pS)I4 and steady-state current-voltage curve characterized by a peak current potential of -30 to -40 mV, were very similar to those of GCAC1. In addition, potent inhibitors GCACl such as NPPB and IAA-94 block s-type channels, too (Schroeder et al., 1993). Because of the striking similarity of GCACl and SLAC on the one hand with respect to voltage dependence and unitary conductance and, on the other, due to their differences in kinetics, one might suggest that GCACl and SLAC/s-type represent different gating modes of the same channel. Thus the peculiar properties of GCACl reviewed here serve as diagnostic tools for answering the question of relationship. VI. VOLUME REGULATION, EXCITATION, AND SIGNAL TRANSDUCTION A. Downregulation of Volume and Turgor
Above we have discussed how the voltage window negative to the reversal potential of K + and positive to those of anions could provide the working range for anion and K f channels to mediate salt release during stomata1 closure (Fig. 12, shaded areas). Under experimental conditions the activity of the anion channel can be triggered by a rise in cytoplasmic Ca2+ (through sudden application of steep Ca2+ gradients; extracellular high). However, a spontaneous increase in anion channel activity emerged sometimes during repetitive voltage ramps in low external Ca”. This observation allows one to speculate that under physiological conditions the increase in Cat+ levels is mediated by voltage-dependent or ligand-dependent gates in the plasma membrane (Schroeder and Hagiwara, 1990a;Cosgrove and Hedrich, 1991) or release from intracellular stores (Blatt et af., 1990). In the activated state the anion permeability was dominating. During inactivation of the anion channel K + permeability increased and generally dominated the whole-cell conductance (Hedrich et al., 1990; Thiel et ul., 1992). The shift in the state of activation of the anion channel was accompanied by a change in the reversal potential of the whole-cell curl4
well.
Later, Schroeder er a / . (1993) related a 36-pS conductance to the s-type current as
24
Rainer Hedrich
FIGURE 12 The working range of anion and potassium channels to mediate salt efflux (A) and signal transduction and excitability (B).
1. Voltage-Dependent Chloride Channels
25
rent. Since the residual current (maximal inactivation) was in the same order of magnitude as the anion currents in the inactivated (background) state it is tempting to suggest that Caz+ and nucleotides modulate the number of active channels or the inactivation gate. The activation state and gating mode (GCACI or SLAC see Section IV,B) of the anion channel depending on Ca2+and nucleotides may thus determine both the magnitude and time course of salt release. In addition to voltage-dependent potassium channels and GCAC 1, three types of stretch-activated channels selectively permeable to Ca2+, K + , and CI- (Cosgrove and Hedrich, 1991)'j may serve as pressure valves in the plasma membrane to adjust the steady-state volume with respect to the settings given by the various effectors and the biochemical machinery of the guard cell. 8. Do Voltage Dependence and Kinetics of CCACl Ask for Excitability? The voltage dependence and kinetics of GCACl described above are reminiscent of N a + , K + , and CaZf channels in excitable membranes (for review, see Hille, 1992). In analogy to the Sodium Hypothesis of Hodgkin and Huxley ( 1952), one can describe the voltage- and time-dependent cycles of activation and inactivation by Z(c,-) = mmexp X . haexp Y G,,-,-,max . ( E -
where C,,, represents the maximal anion conductance of the membrane; m is the activation gate, closed at rest and opening with polynome X , describing the time course of current increase; and h is the inactivation gate which is open at the resting potential and closes exponentially with Y during depolarization (Hedrich et al., 1990). As illustrated in the Hodgkin-Huxley cycle of GCACl (Fig. 13) initial depolarization to slightly negative potentials to -100 rnV activates a few anion channels which in turn further depolarize the plasma membrane toward &-. Due to the voltage- and time-dependent inactivation of GCACl (see Fig. 6), the membrane repolarizes again. Calcium and K + channels may also contribute to the shape of this transient change in membrane potential. Wilting hormone (absicisic acid)-induced or CRAC-like calcium conducIs Please note. that it seems to be unlikely that rnechano-sensitive(MS) channels represent stretch-activated voltage-sensitive channels, since e.g. MS chloride channels have a smaller conductance and different voltage dependence than GCACI).
Rainer Hedrich
26 A
Depolarization
pGcf \ Initial
Inactivation
Depolarization
of GCAC 1
Repolarization Resting potential
B
Voltage gate shifts
Inactivation
(pK*I PH*) FIGURE 13 Hodgkin-Huxley cycle of transient conductance changes in the plasma membrane of guard cells. during excitation, when the initial "input" was a depolarization (A. uoltage change) caused by a Ca'+ permeability (upper cycle) and signal transduction, when (B)ligands modify GCACl directly (lower cycle).
tances (Schroeder and Hagiwara, 1989;Cosgrove and Hedrich, 1991 ;Hoth and Penner, 1992) may account for the initial depolarization (Fig. 13, upper cycle) and outward-rectifying K + channels for enhanced repolarization, under conditions where the voltage gate of GCACl is in its resting position (unchanged by gating modifiers such as auxins or malate).
I . Voltage-Dependent Chloride Channels
27
C. How Do Plant Hormones Work?'6
When auxins, malate, or other stimuli reach their target sites on the anion channel the activation potential of the channel is shifted toward the resting potential of the cell (usually -100 to -160 mV). This shift in activation and peak potential of the anion channel toward hyperpolarized values, a voltage range where KO:, channels are not active (see Fig. 12B), results in the opening of anion channels causing membrane depolarization rather than salt efflux. Transient activation and inactivation of anion channels may provide a potential mechanism for excitability (Fig. 13, lower cycle) in response to sudden changes in water relations (Raschke, 1970), hormone level, and other stimuli (Johnsson et al., 1976). VII. OUTLOOK
In this review describing the current status of anion channel research in plants I have raised many more questions about the properties and function of this channel type than I could answer. In order to answer the queries and to relate plant anion channels to animal counterparts at least three different fields of research might emerge or develop: (i) Future inhibitor-structure channel-function analysis may give further insights into the nature and location of channel sites responsible for gate shifting and block (Fig. 14). In Section IV,C I have shown that structurally nonrelated compounds like growth hormones and anion channel blockers alter the voltage-dependent activity of GCAC 1 in a similar fashion. Thus colabeling of the putative channel protein with azido-auxins and anion channel blockers or antibodies as well as the functional reconstitution of the receptor and channel properties (c.f., see Landry et al., 1989; Palme, 1991) may help to identify the primary sequence of GCACl . (ii) Functional expression of ion channels in heterologous expression systems following injection of poly(A) mRNA or cRNA into frog oocytes or animal cell lines may shed light on the topic. This strategy developed to express or/and clone ion channels from animal tissues (for review, see Rudy and Iverson, 1992) has already been successfully used to express plant outward-rectifying K channels +
'
For the dilemma in explaining the mode of hormone action in general, see Trewavas and Gilroy (1981, 1991) and Guern ef al. (1989).
Rainer Hedrich
28 Release
w Accumulation
FIGURE 14 Schematic drawing of the regulation of GCACI by calcium and nucleotides and voltage, In the upper part a pair of guard cells and the dynamics of chloride movements are illustrated. GCACl is assumed to be a homodimer (due to symmetry considerations) embedded into the 2D lipid matrix. The front view of a half GCACl dimer represents the open state on the left and closed state on the right side. Binding of Ca" and nucleotides (NTP) to sites on the cytoplasmic surface opens the pore leading to the release of anions. The binding pockets of gating modifiers (A) like auxin and malate and inhibitors are located on the external surface. For clearity the putative selectivity filter and pore of the channel outlined by the positive charged a-helix have only been drawn in the left closed state.
I. Voltage-Dependent Chloride Channels
29
\ / Ca", pH, NTP MalateKO2 Voltage
Signal
Volume
Excitability
Transduction Regulation FIGURE 15 GCACl, a channel with multiple regulation sites. Schematic diagram of the various inputs/signals and supposed outputs/physiologicaI responses integrated by the cell through GCACl activity (cf. Fig. 1 ) .
(Cao et af., 1992). It should be noted that inward-rectifying plant K + channels have been cloned by complementation of K + uptakedeficient yeast mutants (Sentenac et a / . , 1992; Anderson et a / . , 1992)." Thus protein isolation, molecular genetics, and functional expression (Schachtman et a / . , 1992) will give clues to protein structure and channel function. (iii) Auxin- or hormone-sensitive mutants may allow signal transduction pathways to be decomposed. Analysis of the early events should help to identify the receptor and transduction elements linked to it. These studies will reveal whether ion channels represent key elements of the transduction machinery or only one of many inputs the cell integrates into a physiological response (Fig. 15).
Acknowledgments I thank D. G. Robinson and K. Raschke for comments on the manuscript as well as P. Dietrich and I. Marten for critical discussion. Help from B. Raufeisen should also be acknowledged. Supported by DFG Grants He 1640 1/1-2.
''
Sequence information might be used now to clone the structurally unknown animal counterpart. Complementation of yeast with anion-efflux channels requires a physiological state, in other words a screening procedure, where anion release is crucial for viability, mutants which in contrast to uptake mutants are to my knowledge not yet described.
30
Rainer Hedrich
References Anderson, J. A., Huplikar, S. S.. Kochian, L. V., Lucas, W. J., and Gaber. R. F. (1992). Functional expression of a probable Arabidopsis thalianu potassium channel in Saccharomyces cerevisiae. Proc. Natl. Acad. Sci. U.S.A. 89, 3736-3740. Armstrong, C. M.. and Cota. G. (1991).Calcium ion as a cofactor in Nat channel gating. Proc. Natl. Sci. U.S.A. 88, 6528-6531. Assmann, S. M.. Simoncini, L., and Schroeder, J. 1. (1985).Blue light activates electrogenic ion pumping in guard cell protoplasts of Vicia f a h a . Nature (London)318, 285-287. Barbara, J.-G.. Stoeckel, H., and Takeda, K. (1994).Hyperpolarization-activated inward chloride current in protoplasts from suspension-cultured carrot cells. Protoplasma, in press. Blatt, M. R. (1991).Ion channel gating in plants: Physiological implications and integration for stomatal function. J . Membr. Biol. W, 95-112. Blatt, M. R.,Thiel, G., and Trentham, D.R. (1990).Reversible inactivation of K + channels of Vicia stomatal guard cells following the photolyses of caged inositol-1.4.5-triphosphate. Nature (London) 346, 766-769. Bormann, J., Hamill, 0. P., and Sakmann, 8 . (1987).Mechanism of anion permeation through channels gated by glycine and y-aminobutyric acid in mouse cultured spinal neurones. J. Physiol. (London) 385, 243-286. Bowling, D. (1987).Measurement ofthe apoplastic activity of K and CI- in the leafepidermis of Commelina communis in relation to stomatal activity. J . Exp. Bot. 38, 1351-1355. Cao. Y.. Anderova, M., Crawford. N. M.. and Schroeder. J. (1992).Expression of an outward-recifiying potassium channel from maize mRNA and complementary RNA in Xenopus oocytes. Plant Cell 4, 961-969. Cole, K. S.,and Curtis, H. J. (1938).Electric impedance of Nitella during activity. J . Gen. Physiol. 22, 3 7-64. Cole, K. S.. and Curtis, H. J. (1939).Electrical impedance of the squid giant axon during activity. J. Gen. Physiol. 22, 649-670. Coleman, H. A. (1986).Chloride currents in Chara-A patch clamp study. J . Membr. B i d . 93, 55-61. Cosgrove, D. J.. and Hedrich, R. (19911. Stretch-activated chloride, potassium, and calcium channels coexisting in the plasma membranes of guard cells of Vkiu fubn L. Planta 186, 143-153. Eisenman, G., and Horn, R. (1983).Ionic selectivity revisited: The role of kinetic and equilibrium process in ion permeation through channels. J. Membr. Biol. 76, 197-225. Falke. L., Edwards, K. L., Pickard. B. G., and Misler. S. A. (1988).A stretch-activated anion channel in tobacco protoplasts. FEES Lett. 237, 141-144. Frizzell, R . A,, and Halm, D. R. (1991).Chloride channels in epithelial cells. Curr. Top. Membr. Tramp. 37, 247-282. Gogelein, H. (1988).Chloride channels in epithelia. Biochim. Biophys. Acta 947, 521-547. Greger, R. (1992).CI channels. In "New Comprehensive Biochemistry: Molecular Aspects of Transport Proteins" (J. J. H. M. de Pont and E. M. Wright, eds.). Elsevier. Amsterdam (in press). Guern, J.. Mathieu. Y., Kurkdjian. A., Manigault, P., Manigault, J., Gillet. B., Beloeil. C.. and Lallemand. J.-Y. (1989).Regulation from within: The hormone dilemma. Ann. Bot. (London) 475-102. Hamill, 0 . P., Marty, A., Neher, E., Sakmann, B.. and Sigworth, F. J. (1981).Improved patch-clamp techniques for high-resolution current recording from cells and cell-free membrane patches. PJuegers Arch. 391, 85-100. +
1 . Voltage-Dependent Chloride Channels
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Hedrich, R.. and Jeromin, A. (1992). A new scheme of symbiosis: Ligand- and voltagegated anion channels in plants and animals. Proc. R . Soc. London. Ser. B 338, 31-38. Hedrich, R., and Neher, E. (1987). Cytoplasmic calcium regulates voltage-dependent ion channels in plant vacuoles. Nature (London) 329, 833-836. Hedrich. R.. and Schroeder, J . I . (1989). The physiology of ion channels and electrogenic pumps in higher plants. Annu. Rev. Plant Physiol. 40, 539-569. Hedrich, R., Schroeder, J. I., and Fernandez, J. M. (1986). Patch-clamp studies o n higher plants: A perspective. Trends Biochem. Sci. 12, 49-52. Hedrich, R.. Busch, H., and Raschke, K. (1990). Ca’+ and nucleotide dependent regulation of voltage dependent anion channels in the plasma membrane of guard cells. EMBO J . 9, 3889-3892. Hedrich. R.. and Marten, I. (1993). Malate-induced feedback regulation of plasma membrane anion channels could provide a CO, sensor to guard cells. EMBO J . 12, 897-901. Hille, 9. (1992). “Ionic Channels of Excitable Membranes.” Sinauer Assoc., Sunderland. MA. Hodgkin. A. L.. and Huxley, A. F. (1952). A quantitative description of membrane current and its application to conduction and excitation i n nerve. J . Phvsiol. (London) 117, 500-544. Hoth, M.. and Penner, R. (1992). Depletion of intracellular calcium stores activates a calcium current in mast cells. Nature (London) 355, 353-356. Humble, D.G., and Raschke, K. (1971).Stomata1opening quantitatively related to potassium transport. Evidence from microprobe analysis. Plant Physiol. 48, 447-453. Imamura. S. (1943). Untersuchungen iiber den Mechanismus der Turgorschwankung der Spaltoffnungsschliesszellen.Jpn. J . Bot. 12, 251-346. Johnsson, M., Issaias, S . , Brogirdh. T., and Johnsson. A. (1976). Rapid. blue-light-induced transpiration response restricted to plants with grass-like stomata. Physiol. Plant. 36, 229-232. Keller, B. U., and Hedrich. R. (1992). Patch clamp techniques to study ion channels from organelles. In “Methods in Enzymology” (B. Rudy and L. E . Iverson. eds.), Vol. 207, pp. 673-681. Academic Press, London. Keller, B. U., Hedrich, R., and Raschke. K. (1989). Voltage-dependent anion channels in the plasma membrane of guard cells. Nature (London) 341, 450-453. Landry, D. W., Akabas. M. H., Redhead, C., Edelman. A.. Cragoe. E. J., Jr.. and AlAwqati, Q. (1989). Purification and reconstitution of chloride channels from kidney and trachea. Science 244, 1469-1472. Laver. D. R. (1991). A surgical method for accessing the plasma membrane of Chara uustralis. Protoplasma 161, 79-84. Lew, R. R. (1991). Substrate regulation of single potassium and chloride ion channels in Arabidopsis plasma membrane. Plant Physiol. 95, 642-647. Linder, B., and Raschke, K. (1992). A slow anion channel in guard cells, activating at large hyperpolarization, may be principal for stomata1 closing. FEBS Lett. 313, 27-30. Lohse, G.,and Hedrich. R . (1992). Characterization of the plasma membrane H +-ATPase from Vicicrfaba guard cells. Modulation by extracellular factors and seasonal changes. Pfanta 188, 206-214. Lunevsky, V . Z . , Zherelova, 0. M., Vostrikov. I . Y . . and Berestovsky, G. N. (1983). Excitation of Choraceae cell membranes a s a result of acitivation of calcium and chloride channel. J . Membr. Biol. 72, 43-58. Marten, I. (1993). Untersuchung der Struktur-Funktions-Beziehung eines Anionenkanals in der Plasmamembran von Schliepzellen aus Viciu faba L. Dissertation, University of Hannover.
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Marten, 1.. Lohse, G . , and Hedrich, R. (1991). Plant growth hormones control voltagedependent activity of anion channels in plasma membrane of guard cells. Nature (London) 353, 758-762. Marten, I., Zeilinger. C., Redhead, C.. Landry. D. W.. Al-Awqati, Q., and Hedrich. R. (1992).Identification and modulation of a voltage-dependent anion channel in the plasma membrane of guard cells by high-affinity ligands. EMBO J. 11, 3569-3575. Marten, I., Busch, H., Raschke, K.. and Hedrich, R. (1993). Modulation and block of plasma membrane anion channels of guard cells by stilbene derivatives. Eur. J . Biophys. 21, 403-408. Morris, C. E. (1990). Mechanosensitive ion channels. J. Membr. Biol. 113, 93-107. Neher, E., and Sakmann, B. (1976). Single-channel currents recorded from membrane of denervated frog muscle fibers. Nutitre (London)260, 779-802. Okihara, K.. Ohkawa, T., Tsutsui, I., and Kasai, M. (1991). A CaZ+-and voltage-dependent CI--sensitive anion channel in the Chara plasmalemma: A patch-clamp study. Plant Cell Physiol. 32, 593-601. Palme, K. (I991). Molecular analysis of plant signalling elements: The relevance of eucaryotic signal transduction models. Int. Reu. Cytol. 132, 223-283. Pardo, L. A., Heinemann, S. H., Terlau. H., Ludewig. U., Lorra, C.. Pongs, 0.. and Stuhmer, W . (1992). Extracellular K t specifically modulates a rat brain K f channel. Proc. Natl. Acad. Sci. U . S . A . 89, 2466-2470. Raschke, K. (1970). Stomata1 responses to pressure changes and interruptions in the water supply of detached leaves of Zea mays L. Plant Physiol. 45, 415-423. Raschke, K . (1979). Movements using turgor mechanisms. Encycl. Plant Physiol., New Ser. 7, pp. 383-441. Raschke, K., and Hedrich, R. (1990). Patch-clamp measurements on isolated guard-cell protoplasts and vacuoles. I n “Methods in Enzymology” (S. Fleischer and B. Fleischer, eds.). Vol. 174, pp. 312-330. Academic Press, San Diego. Redhead, C. R., Edelman, A. E., Brown. D.. Landry. D. W . . and Al-Awqati. Q. (1992). A ubiquitous 64 kDa protein is a component of a chloride channel of plasma and intracellular membranes. Proc. Nail. Acad. Sci. U . S . A . 89, 3716-3720. Robinson, R. A., and Stokes, R. H. (1959). “Electrolyte Solutions.” Butterworth. London. Rudy, B.. and Iverson, L. E., eds. (1992). “Methods in Enzymology.” Vol. 207. Academic Press, London. Sachs, F. (1986). Mechanotransducing ion channels. i n “Ionic Channels in Cells and Model Systems” (R. Latorre, ed.). Plenum, New York, pp. 181-193. Schauf, C. L., and Wilson, K. J. (1987). Properties of single K t and CI- channels in Asc~lepias ruberosa protoplasts. Plant Physiol. 85, 413-418. Schnabl, H. (1981). The compartmentation of carboxylating and decarboxylating enzymes in guard cells. Planta 152, 307-313. Schonknecht, G., Hedrich, R., Junge, W.. and Raschke, K. (1988). A voltage-dependent chloride channel in the photosynthetic membrane of a higher plant. Nature (London) 336, 589-592. Schroeder, J. I. (1987). K+-Kanale in der Plasmamembran von Schliesszellen. Eine PatchClamp Untersuchung molekularer Mechanismen des K+-Transports in hoheren Pflanzenzellen. Dissertation, University of Gottingen. Schroeder, J. I., and Hagiwara, S. (1989). Cytosolic calcium regulates ion channels in the plasma membrane of Vicia faba guard cells. Nature (London)338, 427-430. Schroeder, J. I . , and Hagiwara, S . (199Oa). Repetitive increases in cytosolic Ca?+ of guard cells by abscisic acid activation of nonselective Ca2+permeable channels. Proc. N a f . Acad. Sci. U.S.A. 87,9305-9309.
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Schroeder. J. I . , and Hagiwara, S. (1990b). Voltage-dependent activation of Ca?’-regulated anion channels and K Cuptake channels in Viciafaba guard cells. In “Calcium in Plant Growth and Development” (R. T. Leonard and P. K. Hepler. eds.). Am. SOC.Plant Physiolo. Symp. Ser., Vol. 4, pp. 144-150. Schroeder, J. I . , and Hedrich, R. (1989). Involvement of ion channels and active transport in osmoregulation and signaling of higher plant cells. Trends Biochem. Sci. 5, 187-192. Schroeder, J. I.. Schmidt, C., and Sheaffer, J . (1993). Identification of high-affinity slow anion channel blockers and evidence for stomatal regulation by slow anion channels in guard cells. Planf Cell 5, 1831-1841. Schroeder, J. I . , and Keller, B. (1992). Two types of anion channel currents in guard cells with distinct voltage regulation. Proc. Nail. Acud. Sci. U . S . A . 89, 5025-5029. Schroeder, J . I . , Hedrich, R.. and Fernandez, J. M. (1984). Potassium-selective single channels in guard cell protoplasts of Vicia f a b a . Nature (London)312, 361-362. Schroeder, J. I . , Raschke. K., and Neher, E. (1987). Voltage-dependence of K + channels in guard-cell protoplasts. Proc. Nail. Acad. Sci. U . S . A . 84, 4108-41 12. Sentenac, H.. Bonneaud, N . , Minet, M., Lacroute. F., Salmon, J.-M.. Gaymard, F.. and Grignon, C. (1992). Cloning and expression in yeast of a plant potassium ion transport system. Science 256, 663-665. Serrano. E. E.. Zeiger, E., and Hagiwara. S. (1988). Red light stimulates an electrogenic proton pump in Vicia guard cell protoplasts. Proc. Nail. Acad. Sci. U . S . A . 85,436-440. Skerrett. M.. and Tyerman, S. D. (1994). A channel that allows inwardly directed fluxes of anions in protoplasts derived from wheat roots. Planta 192, 295-305. Speer, M.. and Kaiser. W. M. (1991). Ion relations of symplastic and apoplastic space in leaves from Spiniucia oleracia L. and Pisum satiuirm L. under salinity. Plant Physiol. 97, 990-997.
Tazawa, M., Shimmen. T., and Mimura, T. (1987). Membrane control in the Characeae. Annu. Rev. Plant Physiol. 38, 95-1 17. Terry, B. R.. Tyerman, S. D., and Findlay, G. P. (1991). Ion channels in the plasma membrane of Amaranfhus protoplasts: One cation and one anion channel dominate the conductance. J . Membr. Biol. 121, 223-236. Theo. J . , Elzenga, M., and Van Volkenburgh, E. (1994). Characterization of ion channels in the plasma membrane of epidermal cells of expanding pea (Pisum safiuirm arg) leaves. J . Membr. Biol. 137, in press. Thiel. G . . MacRobbie, E. A. C . , and Blatt, M . R. (1992). Membrane transport in stomatal guard cells: The importance of voltage control. J . Membr. Biol. 126, 1-18. Trewavas, A,. and Gilroy. S. (1981). How do plant hormones work? Planf Cell Enuiron. 4, 203 -228.
Trewavas, A,, and Gilroy. S. (1991). How do plant hormones work? Planf Cell Enuiron. 14, 1-12.
Tyerman. S. D. (1992). Anion channels in plants. Annu. Rev. Planf Physiol. Plant Mol.
Biol. 43, 351-373. Tyerman. S. D., and Findlay, G. P. (1989). Current-voltage curves of single CI- channels which coexist with two types of K t channel in the tonoplast of Chara corallina. J . Exp. Bot. 40, 105-1 17. Van Kirk. C. A , , and Raschke, K. (1978). Presence of chloride reduces malate production in epidermis during stomatal opening. Plant Physiol. 61, 361-364. Zeiger, E.. and Hepler, P. K. (1977). Light and stomatal function: Blue light stimulates swelling of guard cell protoplasts. Science 196, 887-889.
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CHAPTER 2
Molecular Biology of Voltage-Gated Chloride C.hannels Thomas J. Jentsch Center for Molecular Neurobiology, Hamburg University. D-20246 Hamburg, Germany
I. Introduction 11. The CIC Family of C1- Channels
A. CIC-0, the Torpedo Electric Organ CI- Channel B. CIC-I , the Major Skeletal Muscle CI- Channel C. CIC-2, a Ubiquitously Expressed Mammalian CI- Channel D. CIC-K 1 and CIC-K2, Kidney-Specific Chloride Channels 111. Channels or Channel Activators? A, Pkln B. Phospholemman IV. Summary and Outlook References
1. INTRODUCTION
While the molecular characterization of voltage-gated cation channels has made extraordinary progress since the first cloning of a sodium channel by Numa's group (Noda ef al., 1984), molecular biology of voltage-gated chloride channels was nonexistent until late 1990. This may reflect in part a greater interest in cation channels at that time, but is undoubtedly also due to the specific difficulties encountered with chloride channels. The availability of high-affinity ligands for cation channels (e.g., tetrodotoxin for the sodium channel) has greatly facilitated their identification and purification. Unfortunately, there are no inhibitors of similar specificity for voltage-gated chloride channels. Attempts to use less than ideal inhibitors to identify and clone such channels either have failed (Jentsch et al., Currenf Topics in Membranes, Volume 42 Copyright 0 1994 by Academic Press. Inc. All rights of reproduction in any form reserved.
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1989) or are at a stage where functional expression from a cloned cDNA has not yet been reported (Landry et al., 1989; Redhead et al., 1992; Landry et al., 1993; Dermietzel, et al. 1994). Because of the lack of specific inhibitors and of the difficulties of biochemical purification, the first voltage-gated chloride channel family was obtained by expression cloning (Jentsch et al., 1990).This approach obviates the need for identification and purification of the corresponding protein. Homology screening using the first cloned voltage-gated chloride channel, C1C-0 ( Jentsch et al., 1990) as a starting point has led to a growing family of CI- channels (Steinmeyer et al., 1991a; Thiemann et al., 1992; Uchida et al., 1993; Kieferle et al., 1994). Surprisingly, it was reported that expression of phospholemman, a single transmembrane span protein not suspected of being chloride channel, also induces chloride currents (Moorman et al., 1992). However, it seems likely that phospholemman is not a chloride channel, but rather activates endogenous Xenopus oocyte chloride channels upon overexpression (Attali et al., 1993). This may also apply for PI,,, (Krapivinsky et al., 1994), a putative chloride channel isolated from MDCK cells by expression cloning (Paulmichl et al., 1992). This review focuses exclusively on cloned voltage-gated chloride channels. It therefore excludes other cloned CI- channels such as GABA and glycine receptors (Schofield et al., 1987; Grenningloh et al., 1987), which belong to the ligand-gated channel superfamily , and CFTR (Riordan et al., 1989), the protein defective in cystic fibrosis. This review will not cover mdrl, a protein involved in the active transport of hydrophobic substances which enhances volume-activated chloride currents upon overexpression (Valverde et al., 1992). II. THE CIC FAMILY OF CI- CHANNELS A. CIC-0, the Torpedo Electric Organ Cl- Channel
The electric organ of Torpedo and related species is an exceptionally rich source for voltage-gated chloride channels. In the pioneering studies of Chris Miller and colleagues this channel was extensively studied after reconstitution into lipid bilayers (White and Miller, 1979; Miller, 1982; Richard and Miller, 1990; for review, see Miller and Richard, 1990). It is probably one of the best-characterized chloride channels and was the first voltage-gated CI- channel to be cloned (Jentsch et al., 1990). The Torpedo channel is sensitive to micromolar concentrations of the inhibitor DIDS, which probably binds covalently to the channel protein.
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Early work therefore tried to identify the channel protein by DlDS or SITS binding (Taguchi and Kasai, 1980; Jentsch et al., 1989). However, this approach failed due to the low binding specificities of these inhibitors (Jentsch et al., 1989). The cDNA for the Torpedo marmorata channel, now dubbed ClC-0, was finally isolated (Jentsch et al., 1990) using a negative expression cloning approach (Liibbert et al., 1987). It predicts a protein of 805 amino acids (calculated molecular mass = 89 kDa) which was unrelated to any other known protein. Hydropathy analysis suggests 12 to 13 membrane spanning domains (Fig. 1). It lacks a cleavable signal peptide for ER translocation. Based on that observation and on the charge distribution in the neighborhood of the first transmembrane domain (Hartmann et al., 1989) of different members of the CIC chloride channel family, we therefore propose a cytoplasmic localization of the amino-terminus. It should be stressed that the proposed transmembrane topology is hypothetical and will have to be confirmed, e.g., by site-specific antibodies. In fact, recent glycosylation studies (Kieferle et al., 1994) suggest that the D8-D9 linker is extracellular, which requires a revision of the model. Several of the putative transmembrane domains contain charges. These may be involved in the conduction process or may provide a voltage sensor akin to the charged S4 domains of voltage-gated cation channels (Stuhmer et al., 1989). ClC chloride channels do not have a similar segment.
W FIGURE 1 Proposed transmembrane topology of voltage-gated chloride channels of the CIC family. Hydropathy analysis suggests a maximum of 13 transmembrane domains. Some of these domains (D3, D4, D6, D8. and D13) are only weak candidates for transmembrane segments (see, e.g., top of Fig. 3). and the broad hydrophobic regions D9/DIO and D1 I/D12 are assumed to cross the lipid bilayer twice. This model is thus hypothetical and requires experimental confirmation. There is no cleavable signal peptide and the aminoterminus is assumed to be cytoplasmic.
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Using sequence information from the T. marmorata channel (Jentsch et al., 1990), the Torpedo californica channel was subsequently cloned and sequenced (O’Neill et al., 1991). Not surprisingly, it is 97% identical in sequence. Of the 24 amino acid differences (most of them conservative exchanges) only one occurs in a putative transmembrane span (D2). Most differences are located in the amino-terminus or in the large segment between D12 and D13. These parts are also poorly conserved between other members of the C1C family. Expression of CIC-0 in Xenopus oocytes (Jentsch et al., 1990) generates chloride currents which clamp the resting voltage close to the oocyte C1equilibrium potential (-25 to -30 mV). While partially open at resting voltages, the current slowly activates further upon hyperpolarization. Depending on the degree of hyperpolarization, 10 to 40 sec are needed to reach steady-state activation. Deactivation upon stepping back to resting potentials is much slower and needs several minutes to be complete. Once activated by hyperpolarization, the channel is strongly outward rectifying in the negative voltage range (Fig. 2a). This leads to maximum steadystate currents in the range between -80 and - 120 mV. This is similar to results obtained earlier with the T . californica channel expressed in oocytes from total electric organ mRNA (Sumikawa et al., 1984). It is also consistent with the studies of Miller and colleagues (Richard and Miller, 1990) on the reconstituted T . californica channel. It slowly activates within seconds with negative voltage on the cis side of the bilayer; once activated, the current increases (fast) with positive voltages. Comparison of these voltage dependences strongly suggests that the cis side of the bilayer corresponds to the cytoplasmic side of ClC-0. The ion selectivity of C1C-0 was measured in the oocyte system by partially exchanging extracellular chloride with other anions in twoelectrode voltage-clamp experiments (Bauer et al., 1991). These experiments revealed a high selectivity of ClC-0 for chloride. Among the anions tested, only bromide was appreciably permeable, while iodide and SCN actually inhibited the channel. These observations are in agreement with data obtained in the lipid bilayer system. CIC-0 currents in Xenopus oocytes can be inhibited (>80%) using rather high concentrations ( 1 mM) of extracellular DIDS or diphenylamine carboxylate (DPC). In the lipid bilayer system, the channel is quite sensitive to DIDS (in the p M range) from the cis side. This corresponds, however, to the cytoplasm, which explains the poor effect of this inhibitor to the oocyte studies. Reconstituted in lipid bilayers, the Torpedo channel has two conductance states of 9 and 18 pS which appear together in bursts. The singlechannel conductance is linear over a broad voltage range. Miller and
39
2 . Voltage-Gated Chloride Channels
a
c
b
c1c-0
c1c-
1
ClC-2 I
1 sec
1 sec
0 sec
FIGURE 2 Representative voltage-clamp traces showing electrophysiological properties of CIC-0, CIC-I, and CIC-2. Channels were expressed in Xenopus laeuis oocytes and measured after 1-3 days using conventional two-electrode voltage-clamp technique. Top panels show the current necessary to clamp the oocyte to the voltages indicated below. Note that different voltage-clamp programs were used. (a) Properties of CIC-0. The program was chosen to display the properties of the fast gate operating on the “protochannels.” The oocyte was first hyperpolarized to - 140 mV to open the slow gate. Then tail currents were measured by clamping to voltages between + 60 and - 160 mV. This demonstrates the typical outward rectification of activated CIC-0 in the negative voltage range. The current peak observed after the initial hyperpolarization to - 160 mV reflects the closure of the fast gate by hyperpolarization. (b) Properties of CIC-I. Typical features of CIC-1 are the macroscopic inward rectification in the positive voltage range, and the deactivation in the negative voltage range (above =- 100 mV). (c) Properties of CIC-2. This channel is closed in the physiological voltage range ( + 20 to - 100 mV), but opens slowly by stronger hyperpolarization. Deactivation by stepping to positive voltages is faster than the initial activation.
colleagues proposed a “double-barrel” structure of the channel (Miller, 1982; Miller and Richard, 1990). In this model, the channel is a functional homodimer with two identical pores (“protochannels”) of 9 pS which can open and close independently of each other. The gate operating on a “protochannel” is fast and opens with depolarization (or positive voltage on the cis side). This leads to the macroscopic outward rectification of ClC-0 currents after activation. A different common gate operates on both protochannels simultaneously. This gate is slow and opens with hyperpolarization.
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Patch-clamp studies of C1C-0 expressed in Xenopus oocytes (Bauer et al., 1991) show that the single polypeptide encoded by the cloned cDNA is sufficient to generate this double-barreled channel. The single-channel conductance, the voltage dependence, and the binomial distribution of open states were remarkably similar to those of the T . californica channel studied in reconstitution. Thus, all information for generating this complex channel is contained in a single polypeptide. It will be fascinating to investigate these mechanisms by site-directed mutagenesis. In Torpedo, CIC-0 is highly expressed in the electric organ and to a lesser degree in skeletal muscle and in brain (C. Ortland, K. Steinmeyer, and T. J. Jentsch, unpublished). This has been determined both by Northern blotting and by immunofluorescence using several different anti-C1C0 antibodies, Its function in the electric organ is to ensure a high conductivity of the noninnervated membrane during its discharge. Upon receiving a stimulus from the electric lobe, the membrane potential at the innervated surface of an electrocyte will break down due to sodium influx through the nicotinic acetylcholine receptors which are present in very high density. To generate a transcellular voltage, the potential difference across the noninnervated membrane has to remain constant, while a high conductivity is needed to pass large currents. This is accomplished by C1C-0, which is open appreciably under resting conditions and which will increase further its open probability upon depolarization. Since chloride equilibrium potential in the electric organ is probably close to resting potential, the membrane will be clamped to near constant voltages. The voltages across single cells add up to 100 V or more, as the electrocytes are arranged in large stacks on top of each other-like batteries connected in series. In Torpedo skeletal muscle it may play a role identical to ClC-I in mammalian muscle: it ensures electrical membrane stability by clamping the resting potential to the chloride equilibrium potential. 6. CIC- I , the Major Skeletal Muscle CI- Channel
C1C- 1 was cloned from rat skeletal muscle by homology screening with ClC-0 (Steinmeyer et al., 1991a). Mammalian skeletal muscle was an obvious choice for searching for a homolog of the Torpedo channel, since the electric organ is derived from muscle. Also, CIC-0 is expressed in Torpedo skeletal muscle. C1C-1 has an overall homology of about 55% to C1C-0, with a much higher degree of identity in some transmembrane domains. Considerable homology is also present in D13. D13 is a weak candidate for a transmembrane helix based on hydropathy analysis, but the homology found tends
2. Voltage-Gated Chloride Channels
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to support this view (or suggests another important role). CIC-1 is a slightly larger protein than CIC-0 due to N- and C-terminal extensions and due to a larger segment between D12 and D13 (predicted to be 110 kDa). Homology is very weak or nonexistent in the NH,-terminus, the COOHterminus, and the large putative cytoplasmic loop between D12 and D13. ClC-1 is expressed very predominantly in skeletal muscle, with minor expression in smooth muscle and heart. In rat muscle, its mRNA levels increase steeply during the first 3 weeks after birth. This parallels an increase of chloride conductance observed during that time in rat skeletal muscle (Conte Camerino et al., 1989). This suggests a transcriptional regulation of this channel during development which may be analogous to that of sodium channel isoforms (Trimmer et al., 1990) and subunits of the muscle nicotinic acetylcholine receptor (Mishina et al., 1986; Witzemann et a / . , 1989). In fact, the CIC-1 upstream region has typical motifs found in muscle-specific enhancers (Lorenz et a / . , 1994). When expressed in Xenopus oocytes, CIC- 1 induces chloride currents which are inwardly rectifying at positive voltages, and nearly linear in the physiological voltage range, and deactivate (with time constants in the range of 100 msec, depending on the voltage) upon hyperpolarization in excess of =- 100 mV (Fig. 2b). This leads to steady-state chloride currents which are maximal at about -100 mV and decrease with more negative voltages. Chloride conductance in intact muscle fibers from rat diaphragm was reported for the negative voltage range and shows very similar properties (Palade and Barchi, 1977). CIC-1 currents can be blocked by comparatively low concentrations of 9-anthracene carboxylic acid (9-AC) (0. I mM leads to >80% block). This agrees well with the sensitivity of macroscopic muscle C1- conductance to that drug (for review, see Bretag, 1987).The effect of 9-AC onXenopusexpressed ClC- 1 was very slow and dependent on drug concentration. At 0.1 m M , more than 10 min were needed to achieve maximal inhibition, which may mean that this (rather hydrophobic) inhibitor has to enter or cross the lipid bilayer to exert its effect. 9-AC can serve to pharmacologically differentiate between different members of the CIC C1- channel family, since CIC-0 and C1C-2 are only slightly affected even by concentrations of 9-AC as high as 1 mM. Recent studies using noise analysis of C1C- 1 transfected HEK293 cells have revealed a low single-channel conductance (-lpS) of CIC-1 (Pusch e f a / . , 1994). This makes classical single-channel analysis of CIC-1 impossible. Only in rare cases have chloride channels been observed in patch-clamp studies of intact differentiated mammalian skeletal muscle, although other types of channels were easily found (Chua and Eetz, 1991). The properties
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of these chloride channels, however, are inconsistent with CIC-1. In contrast, several different types of chloride channels have been identified in cultured muscle (Blatz and Magleby, 1985; Fahlke et al., 1992; 1993), but their characteristics are also difficult to reconcile with CIC-1 currents. Moreover, characteristics of whole-cell chloride currents in cultured skeletal muscle (Zachar et al., 1992) are incompatible with ClC-1 currents. This may not be surprising, since CIC-1 expression is developmentally regulated (Steinmeyer et al., 1991a), and because denervation of muscle leads to a large decrease in C1- conductance (Camerino and Bryant, 1976; Conte Camerino et al., 1989). Thus, C1C-1 may not be expressed in cultured muscle cells at significant levels. Several results summarized above strongly indicate that CIC-1 is the major skeletal muscle chloride channel: First, it is preferentially expressed in skeletal muscle; moreover, its developmental regulation, electrophysiology, and pharmacology fit with the known characteristics of macroscopic muscle C1- conductance. Skeletal muscle is unusual in that chloride conductance accounts for roughly 7 0 4 0 % of resting conductance (Bretag, 1987). Since chloride equilibrium potential is close to resting potential, this conductance stabilizes membrane voltage in a manner similar to the K + conductance in most other cells. Its pharmacological block by 9-AC slows the rate of repolarization after action potentials. During that time sodium channels can recover from inactivation and fire again, leading to a train of action potentials. This leads to an impairment of muscle relaxation and is similar to findings made in myotonic diseases. Myotonia (muscle stiffness) is a symptom of several human inheritable diseases (Rude1and Lehmann-Horn, 1985). Myotonic dystrophy is a dominant systemic disorder, which in addition to skeletal muscle also affects, e.g., the eye, the CNS, and the heart. The gene responsible for that disease predicts a protein with typical structural features of protein kinases (Fu et al., 1992; Brook et al., 1992). Phosphorylation of different targets in different tissues could explain the multitude of symptoms in myotonic dystrophy. In contrast, autosomal recessive generalized myotonia (GM, Becker’s myotonia) (Becker, 1977) and autosomal dominant myotonia congenita (MC, Thomsen’s disease) (Thomsen, 1876)are purely myotonic diseases. Here symptoms are restricted to skeletal muscles. There are several animal models for (pure) myotonia. A colony of goats with a form of myotonia which probably shows dominant inheritance has been investigated by Bryant and co-workers (Lipicky and Bryant, 1966; Adrian and Bryant, 1974; Bryant and Conte-Camerino, 1991). Several independent mouse mutants displaying a recessive pattern of inheritance have also been described, one of which (ADR) has been thoroughly investi-
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gated by Jockusch and collaborators (Stuhlfauth et al., 1984; Reininghaus et al., 1988; Mehrke et a/., 1988; Jockusch et a/., 1988). A significant decrease in muscle CI- conductance was described in both animal models, although many other parameters were also changed. These included reduced levels of parvalbumin (Stuhlfauth et al., 1984) and altered myosin light-chain phosphorylation (Jockusch et al., 1988).Many of these parameters, however, could be restored back to near normal values by symptomatic treatment of myotonic mice with tocainide (Jockusch et al., 1988) which acts on the sodium channel. This demonstrates that many of the observed changes are secondary to muscle hyperactivity. Thus, alteration of muscle chloride channels, either by mutation or by defective regulation (Brinkmeier and Jockusch, 1987), remained an attractive hypothesis to explain myotonia. The cloning of ClC-I (Steinmeyer et al., 1991a) allowed a direct test of this hypothesis. It was found that ETn, a known mouse transposon, had inserted into an intron interrupting exons coding for the putative transmembrane region D9 (Steinmeyer et al., 1991b). On the mRNA level, this leads to several different splice products, none of which can encode functional channels. In other myotonic mouse strains, no abnormalities were found by Southern or Northern analysis. But since these mutants are known to be allelic, it is clear that myotonia in these strains will also be due to mutations in the CIC-I locus. In fact, point mutations in CIC1 were recently described in these mice (Gronemeier er al., 1994). It is interesting to note that myotonia in mice develops only some weeks after birth (Fuchtbauer et al., 1988).This coincides with the developmental expression of ClC-I (Steinmeyer et al., 1991a) which dominates resting conductance only after 2-3 weeks. Before that time, the contribution of potassium conductance is prevalent (Conte Camerino et al., 1989). In human myotonia, there has been conflicting evidence about the role of chloride conductance. Early work reported a decrease in C1- conductance both in dominant (Lipicky et al., 1971) and in recessive (Rude1 et al., 1988) human myotonia, while more recent reports rather stressed the role of Na+ conductance (Franke et al., 1991), especially for dominant Thomsen’s disease (Iaizzo et al., 1991). In a recent study, we localized the human CIC-I gene on human chromosome 7q32-qter in the vicinity of the T-cell receptor p (TCRB) locus (Koch et al., 1992). Restriction fragment length polymorphisms (RFLPs) in the CLC-1 locus and in the TCRB locus were used to link CLC-I to both the recessive and the dominant form of myotonia in several German families (Koch et af., 1992). Confirming these results, several Canadian families with dominant myotonia were linked to the TCRB locus (Abdalla et al., 1992). One of the restriction endonucleases used to detect RFLPs fortuitously recognized
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a novel restriction site in the CIC-1 locus in two families with Becker’s myotonia, but not in >lo0 control individuals (Koch e f al., 1992). This novel site was then used to search for the underlying mutation, which very likely causes myotonia in these Becker families. A point mutation was found which leads to a phenylalanine to cysteine exchange toward the end of putative transmembrane domain D8 (Koch et al., 1992). This phenylalanine is highly conserved in alI known members of the ClC family, suggesting an important role. In addition, cysteine may lead to the formation of improper disulfide bonds, which may interfere with the correct folding of the protein. This mutation was found in several, but not all, GM families, suggesting the presence of different CIC-1 mutations in GM which is a genetically homogeneous disorder (Koch e f al., 1993). ClC-1 mutations leading to dominant Thomsen-type myotonia were also described (George et a f . , 1993; Steinmeyer ef a f . , 1994), including the mutation present in Thomsen’s own family (Steinmeyer et al., 1994). How can different mutations in the same channel gene lead to recessive and dominant patterns of inheritance? A dominant effect can be easily explained by again-of-function mutation, e.g., a mutation leading to constitutively open channels. To explain a dominant negative mutation as in myotonia, it seems necessary to postulate a (homo)multimeric structure of the channel. A dominant mutation would lead to a “dead” channel subunit which could still associate with the normal subunits encoded by the normal allele and lead to their inactivation. This mechanism was previously proposed to explain the dominant effects of Shaker potassium channel mutants expressed in transgenic Drosophifa (Gisselmann et a f . , 1989). Detailed functional analysis of two Thomsen-type C1C-1 mutations lend strong support for this model (Steinmeyer et al., 1994). It was concluded that the most likely stoichiometry of the homomultimeric channel is four. A recessive mutation could be explained by two different models: (a) the dead channel subunits can no longer associate with the normal one, or (6) they can associate, but the resuIting complex is functional. This model is consistent with the clinical observation (Becker, 1977) that myotonia is more severe in the recessive than in the dominant form: probably in dominant myotonia some normal subunits can escape inactivation by the mutated ones; this would also explain nicely the fact that reduction of muscle chloride conductance was more evident in Becker’s than in Thomsen’s myotonia. C. CIC-2, a Ubiquitously Expressed Mammalian Cl- Channel
C1C-2 was originally cloned from heart and brain cDNA libraries, but it soon became clear that it is ubiquitously expressed (Thiemann et al.,
2. Voltage-Gated Chloride Channels
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1992). The complete cDNA was then obtained from rat brain, where expression is especially high. Overall sequence homology is again about 50% to both ClC-0 and C1C1, with highest degree of identity in transmembrane regions (Fig. 3). Expression in Xenopus oocytes gave currents which activated very slowly (within seconds) upon strong, unphysiological hyperpolarization (in excess of -90 mV) (Fig. 2c). More than 20 sec were needed to reach steadystate activation. In contrast, deactivation upon stepping back to holding potentials of -30 mV was several times faster. Once activated by hyperpolarization, it has a nearly linear, slightly inward-rectifying current-voltage relationship. Its conductivity sequence is C k B r > I . Extracellular DIDS (1 mM) was nearly ineffective in blocking it, while 1 mM DPC or 9-AC were able to block it by roughly 50%. By Northern analysis, CIC-2 expression was demonstrated in rat skeletal muscle, heart, brain, lung, kidney, pancreas, stomach, intestine, and liver. Since this could have meant that CIC-2 is expressed in a cell type common to all these tissues (e.g., fibroblasts or vascular smooth muscle cells), Northern analysis was repeated with several different cell lines and was again found to be ubiquitous. This included fibroblasts (NIH 3T3), epithelial cells (e.g., T84, CFPAC-I, LLC-PKl), and neuronal-like cells (Neuro2a, PC-12). In some tissues (heart, fetal skeletal muscle, and T84 human colon epithelial cells) expression was confirmed by additional cDNA cloning. Expression in cells affected by cystic fibrosis is especially interesting as one could speculate that it could be used to bypass the chloride transport defect in that disease. A prerequisite, however, is expression of CIC-2 in apical membranes. This has not yet been examined. It is very unlikely that strong hyperpolarization represents the physiological means of activating CIC-2, since these voltages are not reached in vivo. On the other hand, the ubiquitous expression suggests a function important for every cell. In many cells regulatory volume decrease is accomplished by the parallel opening of independent C1- and K + channels (Hoffmann and Simonsen, 1989). We thus hypothesized that C1C-2 could have a role in cell volume regulation. In fact, when expressed in oocytes, C1C-2 is activated by hypotonicity (Griinder et al., 1992). Thus C1C-2 has a basic function for cell biology by mediating regulatory volume decrease. Extensive site-directed mutagenesis studies identified a N-terminal domain in C1C-2 which is essential for activation by cell swelling (Griinder et al., 1992). This domain is position-independent, as it can be transplanted to the C-terminus without loss of function. A model was proposed in which this domain binds to a putative receptor on the cytoplasmic side of the channel; hypotonicity and hyperpolarization were postulated to reduce the affinity of this receptor, resulting in channel activation (Griinder et al., 1992).
46
Thomas J. Jentsch 1
2 34 5 6 7 8
9101112
o o o o o n o n mm
250
Y
8
500
. .... ... ,
750
"\\,
500 750 CIC-1 FIGURE 3 Homology between CIC-I and CIC-2 chloride channel proteins. A dot-plot matrix is shown where homology is shown by dots at the appropriate positions. The top panel shows the hydropathy analysis of CIC-I for comparison. It is evident that homology is found mainly in putative transmembrane regions. This includes D13, which on the basis of hydrophobicity analysis is only a poor candidate for a transmembrane span. No homology exists at both ends of the protein nor in the putative loop between D12 and D13.
250
2. Voltage-Gated Chloride Channels
47
D. CIC-K I and CIC-K2, Kidney-Specific Chloride Channels Using primers against regions conserved between different members of CIC chloride channels and the polymerase chain reaction (PCR), Uchida et al. (1993) isolated a new, kidney-specific member (CIC-Kl) of this gene family from the rat. Using a similar approach and homology screening, Kieferle et al. (1994) obtained a different, highly homologous member of this gene family (rCIC-K2), and again two highly homologous cDNAs (hC1C-Ka and hC1C-Kb) from human kidney. The high degree of identity within a species does not allow correlation between human proteins and their rat counterparts. Using RT-PCR on microdissected tubule segments, the intrarenal distribution of these putative channels was investigated. While rC1C-Kl is most highly expressed in the thin ascending limb of Henle's loop (Uchida et al., 1993),the thick ascending limb and the distal convoluted tubule (Kieferle et al., 1994), rClC-K2 shows a broader distribution (Kieferle et al., 1994). Interestingly, rC1C-K1 message could be increased by dehydration of the animals (Uchida et al., 1993). While Uchida et al. (1993) reported that expression of CIC-Kl in Xenopus oocytes leads to time-independent outwardly rectifying chloride currents, no expression could be obtained in the second study (Kieferle et al., 1994). Thus, though it is tempting to speculate that these proteins are involved in the reabsorption of chloride along the nephron, a defined physiological role for these CIC members has yet to be demonstrated. 111. CHANNELS OR CHANNEL ACTIVATORS?
Paulmichl et al. (1992) have identified a totally different protein inducing CI- currents by positive expression cloning using Xenopus oocytes. The source of the messenger RNA was MDCK cells, a well-characterized epithelial cell line derived from dog kidney. A clone was finally isolated, which, when functionally expressed in oocytes, induced strongly outwardrectifying chloride currents. Only very small currents were present at physiological voltages (-50 to -70 mV). At positive voltages, (+ 6 0 mV), currents inactivated slowly with a time constant of =250 msec. Currents could be blocked by extracellular DIDS (1C5, = 20 p M )and NPPB (5nitro-2-(3-phenylpropylamino)-benzoicacid, IC,, = 1.5 pM),known inhibitors of chloride channels. They could not be influenced by intracellular calcium, suggesting that Zcln is not due to an activation of the endogenous
48
Thomas J. Jentsch
Ca-activated oocyte chloride channel. Iclnis inhibited by extracellular nucleotides, including ATP, ADP, GTP, CAMP,and cGMP in rather high concentrations, with 70% inhibition reached by millimolar levels of CAMP and cGMP. It came as a surprise that the rather small protein encoded by the cDNA (235 amino acids, predicted molecular mass 26 kDa) did not have any hydrophobic domain predicted to cross the lipid bilayer as an a-helix. Paulmichl et al. therefore proposed a model in which four amphipathic p-strands cross the membrane. Assuming that the functional unit of Zcln is a dimer (which is not known), the pore of the putative channel might be formed by an eight-stranded p-barrel. A similar model has been proposed previously for the voltage-gated VDAC channel from yeast mitochondria (porin) (Blachly-Dyson et al., 1990).However, there is no sequence homology to VDAC, nor to any other known protein. Site-directed mutagenesis suggested that Zcln is a C1- channel, and not just an activator of preexistent channels. The sequence of Z,, predicts a nucleotide binding domain (GXGXG), which according to the model is located near the extracellular region. In principle, it could mediate the inhibitory effect of extracellular nucleotides. Mutating the first glycine of the consensus sequence (to alanine) indeed largely reduced the sensitivity to extracellular CAMP, while mutating all three glycines totally abolished its inhibitory effect (Paulmichl et al., 1992). The triple mutation also slightly changed channel kinetics and made currents dependent on extracellular calcium. Thus, Zcrn may represent a novel chloride channel with an unusual structure. Its function, including the role of extracellular nucleotides in its regulation, is unclear, especially since currents are very small in the physiological voltage range. It is expressed in many different tissues (Paulmichl et al., 1992; Ishibashi et al., 1993) and may have some basic role for the cell. Paulmichl and co-workers have shown that anti-sense oligonucleotides directed against Zcln suppress the endogenous volume-activated chloride current of 3T3 fibroblasts (Gschwentner et al., 1994). In addition, injection of antibodies directed against pZclninto Xenopus oocytes suppressed their endogenous swelling-activated chloride current (Krapivinsky et al., 1994). However, serious doubts about the role of pZC,, as a chloride channel have been raised after it was found to be a soluble, cytoplasmic protein which interacts with actin and other proteins (Krapivinsky et al., 1994). Therefore, it was suggested that it plays a role in mediating channel activation induced by cell swelling by interacting with the cytoskeleton. However, a specific physiological role for pZcl, in this regulation has still to be demonstrated as gross alteration of the cytoskeleton (e.g., by cytochalas-
2 . Voltage-Gated Chloride Channels
49
ins) also can lead to changes in volume regulation. Moreover, the results obtained by mutagenesis (Paulmichl et a/., 1992) need to be explained, and the possibility remains that a small proportion of pl,,, inserts into the plasma membrane t o form a channel.
B. Phospholemman
Surprisingly phospholemman, a small polypeptide of 72 amino acids with a single predicted transmembrane span, also induces chloride currents when overexpressed in Xenopus laeuis oocytes (Moorman et a/., 1992). These currents activate very slowly upon hyperpolarization with a threshold potential near -80 mV and are intriguingly similar to those observed with the entirely different ClC-2 protein (Thiemann et a/., 1992). ExtracelM a r acidification increased phospholemman-induced chloride currents, which were still dependent on hyperpolarization. Currents could be blocked by injection of9-AC into the oocytes. Currents were also inhibited by extracellular barium (lC50= 0.36 mM), which is normally used to block K + channels. There was no dependence on intracellular calcium, since injection of EGTA into the oocyte had no effect on the expressed current. This observation also excludes the possibility that phospholemman acts by activating endogenous oocyte Ca-dependent CI- channels, though it may activate other Xenopus oocyte chloride channels. Moorman et a f . (1992) also mutated phospholemman in an attempt to ascertain whether it is a chloride channel by itself. In fact, mutating two amino acids in the transmembrane span (G25P and F28Y) changed kinetics of channel activation. However, in contrast to changes in ion selectivity, changes in kinetics are not particularly strong arguments in proving that the mutated protein is an ion channel. Phospholemman (first called " 15-kDa protein") has been originally identified as the major target for phosphorylation by CAMP-dependent kinase and protein kinase C in the sarcolemma of the myocardium (hence its name). It is also phosphorylated in uivo in response to isoproterenol (Presti et af., 1985). Phospholemman is expressed in several muscular tissues and in liver, but not in brain or kidney. Its sequence (Palmer et a/., 1991) predicts a protein with a cleavable signal peptide for ER translocation and a single hydrophobic transmembrane span. Significant sequence homology was found to a partial amino acid sequence of the so-called y-subunit of the (Na,K)-ATPase (Collins and Leczyk, 1987; Mercer et af.,1993), a small protein copurifying with the ATPase, but whose function is unknown. This homology includes the putative transmembrane region. It will be interesting to see whether these proteins belong to the same gene family
50
Thomas J. Jentsch
and whether the “y-subunit” is also able to induce currents when expressed in oocytes. Limited homology was also found to phospholamban (Simmermann et al., 1986), a major substrate for phosphorylation in cardiac sarcoplasmic reticulum believed to regulate Ca-ATPase activity. This homology, however, is restricted to the recognition sites for phosphorylation of phospholamban. Although interest in phospholemann originally stemmed from phosphorylation studies, Moorman et al. (1992) unfortunately do not report experiments aimed at studying the effect of phosphorylation on chloride currents. Thus it is unclear whether it has any relationship to cardiac chloride currents stimulated by adrenergic substances (Bahinski et al., 1989; Harvey and Hume, 1989; Ehara and Ishihara, 1990), which have a very different I-V relationship and are probably mediated by CFTR (Nagel et al., 1992). The physiological role of phospholemman remains to be determined. As in the case of pIcln,there are now doubts that phospholemman is a chloride channel. First, hyperpolarization-induced chloride currents are observed in some batches of noninjected oocytes (Kowdley et al., 1994). These currents display an I > CI halide selectivity which differs from the C1 > I selectivity of C1C-2 (which is also activated by hyperpolarization), but coincides with that observed with phospholemman overexpression. A common feature of both currents is also their sensitivity to external barium. Second, overexpression of ZsK (minK), a protein having also just a single transmembrane span and postulated to be a potassium channel (Takumi et al., 1988), also induces currents resembling phospholemmaninduced currents (Attali et al., 1993). Further, overexpression of a dead ClC-1 mutant also induces similar currents (Steinmeyer et al., 1994). Thus, it seems likely that phospholemman activates chloride channels endogenous to the cells in which it is overexpressed. Whether this activation plays a physiological role or is just an artifact of overexpression remains to be determined.
N. SUMMARY AND OUTLOOK Due to the impact of molecular biological techniques, an increasingly complex structural picture of chloride channels has emerged during the past few years (Table I). While for the C1C family of chloride channels there seems to be no reasonable doubt that at least some of their members (ClC-0, - I , and -2) represent chloride channels, the role of pIcln and phospholemman as chloride channels has been questioned recently. There is good reason to believe that these proteins activate chloride channels
TABLE TABLE I I Cloned Voltage-Gated Chloride Channels Channel Activators) Cloned Voltage-Gated Chloride Channels (or(or Channel Activators) Tissue distribution Tissue distribution
Function Function
Voltage dependence Voltage dependence
Pore Pore
Structure Structure 12 hydrophobic - 12-hydrophobic
Torpedo Torpedo Electric organ, skeletal Electric organ, skeletal muscle. brain muscle. brain
Stabilization of V Slow Slow opened Stabilization of V gategate opened by by in electric hyperpolarization, in electric hyperpolarization, fastfast organ opened organ andand gategate opened by by depolarization muscle depolarization muscle
10 pS, Linear 10 pS, Linear doubledoublebarrel barrel > Br, CI CI > Br, I block I block
CIC-I CIC-I
Mammals Mammals Skeletal muscle Skeletal muscle (smooth muscle, heart) (smooth muscle, heart)
Stabilization of V Deactivates Deactivates with Stabilization of V with in skeletal hyperpolarization. in skeletal hyperpolarization. muscle defect: inward rectifier muscle defect: inward rectifier in in myotonia positive V range myotonia positive V range
- I -pI s p s > Br > Br > I> I CI CI I block I block
TMDs -12-12 TMDs =tetramer =tetramer
CIC-2 CIC-2
Mammals Mammals ubiquitous ubiquitous
volume CellCell volume regulation regulation
Slowly activates with Slowly activates with -3-5-3-5p s p s hyperpolarization, closed CI CI 2 Br hyperpolarization, closed 2 Br > I> I at resting V linear once I block I block at resting V linear once activated activated
TMDs -12 -12TMDs
CIC-KI CIC-KI
CI reabsorption Mammalian kidney or outward rectifier CI reabsorption Mammalian kidney ? ? ? or? outward rectifier (more restricted than - K2) (more restricted than - K2) CI reabsorption? Mammalian kidney CI reabsorption? Mammalian kidney ? ?
CIC-0 CIC-0
CIC-K2 CIC-K2 Pkl.Pkl.
Mammals Mammals Broad distribution Broad distribution (e.g., kidney, lung, (regulator ?) ?) (e.g., kidney, lung, (regulator leukocytes) leukocytes) Phospholemman Mammals Mammals Phospholemman (regulator Muscle, heart, liver, (regulator ?) ?) Muscle, heart, liver, brain, kidney notnot brain, kidney
volume CellCell volume regulation (?) (?) regulation
?? ??
transmembrane transmembrane domains domains (TMD) (TMD)
TMDs ? p ?s p s -12-12 TMDs > CI > CI > I>?)I ?) (Br(Br 12TMDs ? ? 12TMDs
--
Outward rectifier Outward rectifier deactivates with deactivates with depolarization, inhibited depolarization, inhibited nucleotides by by nucleotides
?? ??
P-barrels P-barrels ? ?
Slowly activates Slowly activates withwith hyperpolarization hyperpolarization
?? ??
I single TMD I single TMD
52
Thomas J. Jentsch
endogenous to the cell used for expression, although a direct role as a chloride channel cannot be ruled out at present. Interpretation of expression data should be very cautious, especially if currents resemble those observed in control cells. Rigid criteria should be met before a claim that a cloned protein represents a chloride channel is justified. The complexity of the picture is likely to increase dramatically in the next few years as new members of cloned channel families are relatively easy to identify by methods based on homology. In addition, new unrelated families are likely to be identified by sophisticated expression cloning strategies. Challenges for the future will be the molecular identification of new channels, the elucidation of their physiological roles, and the dissection of their structure-function relationships by site-directed mutagenesis. The coming years promise to be very exciting. Acknowledgments I thank the co-workers in my lab for their enthusiasm, hard work, and stimulating discussions. The work in this laboratory is supported by the Bundesministerium fur Forschung und Technologie, the Deutsche Forschungsgemeinschaft (Grants Je164/1-1, Je164/2-1), the Cystic Fibrosis Foundation, and the Muscular Dystrophy Association.
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Q. (1989). Purification and reconstitution of chloride channels from kidney and trachea. Science 244, 1469-1472. Landry, D. W., Sullivan. S . , Nicolaides. M.. Redhead. C., Edelman. A., Field, M . . AlAwqati. Q., and Edwards, J . (1993). Molecular cloning and characterization of p64. a chloride channel protein from kidney microsomes. J . B i d . Chem. 268, 14948-14955. Lipicky, R . J . . and Bryant, S. H. (1966).Sodium. potassium. and chloride fluxes in intercostal muscle from normal goats and goats with hereditary myotonia. J . Gen. Physiol. 50, 89-111. Lipicky. R. J . , Bryant, S . H., and Salmon. J. H. (1971). Cable parameters, sodium. potassium, chloride, and water content, and potassium efflux in isolated external intercostal muscle of normal volunteers and patients with myotonia congenita. J . Clin. Invest. 50, 2091 -2 103. Lorenz, C., Meyer-Kleine, C., Steinmeyer, K . . Koch. M. C.. and Jentsch, T. J . (1994). Genomic organization of the human muscle chloride channel CIC-I and analysis of novel mutations leading to Becker type myotonia. Hum. Mol. Genef.3, in press. Lubbert. H.. Hoffman, B. J . . Snutch, T. P.. van Dyke. T.. Levine, A. J.. Hartig. P. R., Lester, H. A., and Davidson, N. (1987). cDNA cloning of a serotonin 5-HTlc receptor by electrophysiological assays of mRNA-injected Xenopus oocytes. Proc. Natl. Acad. Sci. U . S . A . 84, 4332-4336. Mehrke. G., Brinkmeier, H., and Jockusch. H. (1988). The myotonic mouse mutant adr: Electrophysiology of the muscle fiber. Muscle Nerve 11, 440-446. Mercer. R . W . , Biemesderfer, D., Bliss, Jr.. D. P.. Collins, J . H.. and Forbush 111, B. ( I 993). Molecular cloning and immunological characterization of the ypolypeptide. a small protein associated with the Na,K-ATPase. J . Cell Biol. 121, 579-586. Miller, C. (1982). Open-state substructure of single chloride channels from Torpedo electroplax. Philos. Trans. R . Soc. London, Ser. B 299, 401-41 1. Miller, C.. and Richard, E. A. (1990). The voltage-dependent chloride channel of Torpedo electroplax. Intimations of molecular structure from quirks of single-channel function. In “Chloride Channels and Carriers in Nerve. Muscle, and Glial Cells” (F. J. AlvarezLeefmans and J . M. Russell, eds.), pp. 383-405. Plenum, New York. Mishina, M., Takai, T., Imoto, K., Noda, M . . Takahashi. T., Numa, S.. Methfessel, C., and Sakmann, B. (1986). Molecular distinction between fetal and adult forms of muscle nicotinic acetylcholine receptor. Nature (London) 321, 406-41 1. Moorman, J . R . , Palmer, C. J., John, J . E.. 111, Durieux. M. E., and Jones, L. R. (1992). Phospholemman expression induces a hyperpolarization-activated chloride current in Xenopus oocytes. J . Biol. Chem. 267, 14551-14554. Nagel, G., Hwang. T.-C., Nastiuk, K. L., Nairn, A. C., and Gadsby, D. C. (1992). The protein kinase A-regulated cardiac CI- channel resembles the cystic fibrosis transmembrane conductance regulator. Nature (London) 360, 81-86. Noda, M., Shimizu. S . , Tanabe, T., Takai. T., et a/. (1984). Primary structure ofElec,tuophorus electricits sodium channel deduced from cDN A sequence. Nature (London) 312, 121-127. O’Neill. G. P., Grygorczyk, R., Adam, M., and Ford-Hutchinson, A. W. (1991). The nucleotide sequence of a voltage-gated chloride channel from the electric organ of Torpedo californica. Biochim. Biophys. Acta 1129, 131-134. Palade, P. T.. and Barchi, R . L. (1977). Characteristics of the chloride conductance in muscle fibers of the rat diaphragm. J . Gen. Physiol. 69, 325-342. Palmer, C. J . , Scott, B. T., and Jones, L. R. (1991). Purification and complete sequence determination of the major plasma membrane substrate for CAMP-dependent protein kinase and protein kinase C in myocardium. J . Biol. Chem. 266, 1 1 126-1 1130.
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Paulmichl, M., Li, Y., Wickman, K.. Ackermann. M., Peralta, E.. and Clapham. D. (1992). New mammalian chloride channel identified by expression cloning. Nature (London) 356, 238-241. Presti, C. F., Jones, L. R., and Lindemann. J. P. (1985). Isoproterenol-induced phosphorylation of a 15-kilodalton sarcolemmal protein in intact myocardium. J . Biol. Chem. 260, 3860-3867. Pusch, M . , Steinmeyer, K., and Jentsch. T. J. (1994). Low single channel conductance of the major skeletal muscle chloride channel, CIC-I. Biophys. J . 66, 149-152. Redhead, C. R., Edelman, A. E., Brown. D.. Landry, D. W.. and Al-Awqati. Q. (1992). A ubiquitous 64-kDa protein is a component of a chloride channel of plasma and intracellular membranes. Proc. Natl. Acad. Sci. U.S.A.89, 3716-3720. Reininghaus. J.. Fiichtbauer, E. M.. Bertram. K . . and Jockusch. H. (1988). The myotonic mouse mutant ADR: Physiological and histochemical properties of the muscle. Muscle Nerve 11, 433-439. Richard, E. A., and Miller, C. (1990). Steady-state coupling of ion-channel conformations to a transmembrane ion gradient. Science 247, 1208-1210. Riordan, J. R.. Rommens. J . M.. Kerem. B.-S., Alon. N.. Rozmahel. R.. Grzelczak. 2.. Zielenski, J . . Lok. S.. Plavsic. N.. Chou. J.-L., Drumm. M. L.. lannuzzi. M . C.. Collins, F. S . . and Tsui. L.-C. (1989). Identification of the cystic fibrosis gene: Cloning and characterization of complementary DNA. Science 245, 1066- 1073. Rudel. R.. and Lehmann-Horn, F. (1985). Membrane changes in cells from myotonia patients. Phvsiol. Rev. 65, 310-356. Riidel, R.. Ricker. K . . and Lehmann-Horn. F. (1988). Transient weakness and altered membrane characteristics in recessive generalized myotonia 1Becker). M t w l e N ; w c 11, 202-21 I . Schofield, P. R., Darlison, M. G . , Fujita, N.. Burt, D. R., Stephenson, F. A., Rodriguez. H., Rhee. L. M., Ramachandran, J., Reale. V . , Glecorse. T. A,. Seeburg, P.. and Barnard, E. A. (1987). Sequence and functional expression of the GABA, receptor shows a ligand-gated receptor super-family. Nature (London)328, 221-227. Simmermann, H. K. B., Collins, J . H., Theibert. J. L., Wegener, A. D.. and Jones, L . R. (1986). Sequence analysis of phospholamban. J . Biol. Chem. 261, 13333-13341. Steinmeyer, K., Ortland. C., and Jentsch. T. J. (1991a). Primary structure and functional expression of a developmentally regulated skeletal muscle chloride channel. Nature (London) 354, 301-304. Steinmeyer, K., Klocke. R., Ortland. C., Gronemeier. M.. Jockusch. H.. Griinder. S.. and Jentsch, T. J. (1991b). Inactivation of muscle chloride channel by transposon insertion in myotonic mice. Nature (London) 354, 304-308. Steinmeyer, K., Lorenz. C., Pusch, M., Koch, M. C., and Jentsch. T. J. 119941. Multirneric structure of CIC-I chloride channel revealed by mutations in dominant myotonia congenita (Thomsen). EMBO J . 13, 737-743. Stuhlfauth, I . , Reininghaus, J.. Jockusch. H., and Heizmann, C. W. (1984). Calcium-binding protein, parvalbumin, is reduced in mutant mammalian muscle with abnormal contractile properties. Proc. Narl. Acad. Sci. U.S.A. 81,4814-4818. Stiihmer, W., Conti, F., Suzuki, H . , Wang, X., Noda, M., Yahagi, N., Kubo, H., and Numa, S. (1989). Structural parts involved in activation and inactivation of the sodium channel. Nature (London) 339,597-603. Sumikawa, K., Parker, I., Amano, T., and Miledi, R. (1984). Separate fractions of mRNA from Torpedo electric organ induce chloride channels and acetylcholine receptors in Xenopus oocytes. EMBO . I 3, . 2291-2294. Taguchi, T., and Kasai, M. (1980). Identification of an anion channel protein from electric organ of Narke japonica. Biochem. Biophys. Res. Commun. %, 1088-1094.
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Takumi. T.. Ohkubo. H.. and Nakanishi. S. (1988). Cloning of a membrane protein that induces a slow voltage-gated potassium current. Science 242, 1042-1045. Thiemann. A., Grunder. S., Pusch. M.. and Jentsch. T . J. (1992). A chloride channel widely expressed in epithelial and non-epithelial cells. N a t u r e (London)356, 57-60. Thornsen, J. ( I 876). Tonische Krampfe in willkurlich beweglichen Muskeln in Folge von ererbter psychischer Disposition. A r c h . Psychiatr. Neruenkr. 6, 702-718. Trimmer. J. S.. Cooperman, S. S . . Agnew. W. S. , and Mandel. G. (1990). Regulation of muscle sodium channel transcripts during development and in response to denervation. D e u . Biol. 142, 360-367. Valverde. M. A.. Diaz. M.. Sepulveda. F. V.. Gill. D. R.. Hyde. S. C.. and Higgins. C. F. ( 1992). Volume-regulated chloride channels associated with the human multidrugresistance P-glycoprotein. Ntitrrre (Londott)355. 830-833. Uchida. S.. Sasaki. S., Furukawa. T.. Hiraoka. M., Imai. T.. Hirata. Y.. and Marumo. F. (1993). Molecular cloning of a chloride channel that is regulated by dehydration and expressed predominantly in kidney medulla. J. Biol. Chcwt. 268. 3821-3824. White, M . M.. and Miller. C. (1979). A voltage-gated anion channel from the electric organ of Torpedo c.crlififorniccr. J . Biol. Chem. 254, 10161-10166. Witzemann. V.. Barg. B . . Criado. M.. Stein. E.. and Sakmann. B . (1989). Developmental regulation of five subunit specific mRNAs encoding acetylcholine receptor subtypes in rat muscle. FEBS Lett. 242, 419-424. Zachar. E.. Fahlke. C.. and Riidel. R . (1992). Whole-cell recordings of chloride currents in cultured human skeletal muscle. efhegers A r c h . 421, 101-107.
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CHAPTER 3
An IAA-Sensitive Vacuolar Chloride Channel Qais Al-Awqati Departments of Medicine and Physiology. College of Physicians and Surgeons. Columbia University. New York, New York 10032
I . Introduction A. p64. a Vacuolar C1 Channel B . Cystic Fibrosis 11. The IAA-Sensitive Chloride Channel A. Purification and Reconstitution B . p64, a Component of the IAA-Sensitive CI Channel in Kidney and Other Cells C. Cloning of the p64 cDNA D. p64 Is Not Targeted to the Plasma Membrane of Nonepithelial Cells but in Epithelial Cells It Is Located in the Apical Plasma Membrane References
I. INTRODUCTION All eukaryotic cells tested have one or more types of chloride channel. In some cells they are present in the plasma membrane where they participate in the control of cell volume (probably in most cells), membrane potential (in muscle and nerve), or the secretion of NaCl and water (in epithelia). In addition, chloride channels have been found in intracellular organelles such as endosomes, lysosomes, and Golgi where they are present in parallel to an electrogenic proton translocating ATPase and hence can control the pH gradient and membrane potential of these organelles. Based on single-channel behavior, chloride channels exhibit marked diversity in conductance, current-voltage relation, and regulation by modulators. Using these functional criteria, it was found that a single cell might Currrrrr Topics in Membranes, Volume 42
Copyright 0 1994 by Academic Press. Inc. All rights of reproduction in any form reserved.
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contain as many as three types of plasma membrane C1 channels, in addition to the one or more types of intracellular channels. Studies have identified a number of molecules that code for C1 channels which do not belong to a single family. The GABA and glycine receptors resemble the nicotinic receptor, a cation channel (Olsen and Tobin, 1990). The cystic fibrosis gene product (CFTR) and the multidrug resistance gene bear similarities to ATP-dependent solute transporters (Riordan, 1992; Welsh et al., 1992). A family of voltage-sensitive chloride channels found in Torpedo electric organ, mammalian muscle, and epithelial cells do not resemble any known sequences (Steinmeyer et al., 1991). Porins in outer membranes of bacteria and mitochondria do not even contain “canonical” transmembrane hydrophobic helices (Weiss and Schulz, 1992). Neither does a channel cloned from MDCK epithelia (Paulmichl et al., 1992). This diversity suggests that there may be even more types of chloride channels to be discovered. Indeed, using the biochemical approach of solubilization and reconstitution, we (Landry et al., 1989) and others (Ran and Benos, 1991) have found two additional C1 channels in epithelial cells. A. p64, a Vacuolar Cl Channel
Most of the studies referred to above were directed toward the identification of plasma membrane C1 channels. We had discovered that Golgi, endosomes, and secretory granules contain chloride channels which are intimately involved in the control of the pH gradient generated by the H+-ATPase (Glickman et al., 1983). That this C1 channel can control vacuolar pH in vivo was shown when we found that secretagogues induce acidification of secretory granules by opening C1 channels (Barasch et al., 1988). Since we had demonstrated that Golgi vesicles also contain C1 channels and were not maximally acidified, we speculated that control of Golgi pH might profoundly affect the function of Golgi enzymes many of which are pH sensitive (Al-Awqati, 1986). To provide molecular reagents for further analyses of these processes we decided to purify the C1 channel of intracellular organelles which we term here as a vacuolar chloride channel. We do not at present know whether there is a single molecular species that codes for vacuolar C1 channels or whether there are many. Given the level of molecular diversity in C1 channels already identified, it is probable that there are several kinds of intracellular C1 channels. As discussed in detail below, we used an inhibitor derived from ethacrynic acid, IAA-94, to purify the drug binding proteins from bovine kidney cortex intracellular vesicles and showed by reconstitution that the affinity-purified proteins contain a C1 channel
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(Landry et al., 1987, 1989). Two proteins were eliminated as drug binding proteins and one of the remaining, a 64-kDa protein (p64), generated a specific antibody. This antibody was able to deplete all C1 channel activity from bovine kidney cortex suggesting that it is a necessary component of the vacuolar channel (Redhead et af., 1992). We cloned and sequenced the cDNA for p64 and obtained a novel sequence of a membrane protein. Using antibodies we found that p64 is located in the perinuclear region (probably Golgi) and in the apical membrane of some epithelial cells. 8. Cystic Fibrosis
The discovery that the phenotypic defect in cystic fibrosis is an abnormality of activation of an epithelial C1 channel has galvanized the field of study of C1 channels and awarded it a high visibility (Schoumacher et al., 1987; Welsh and Liedtke, 1986). The gene, CFTR, was rapidly identified (Welsh and Liedtke, 1986) and its function was analyzed in detail by transfection into heterologous cells where it causes the appearance of a new cyclic AMP and an ATP-activated small C1 channel with a linear I-V relationship (Riordan, 1992; Welsh et af., 1992). The major mutation, AF508, appears to be a temperature-sensitive mutation that causes an abnormality in proper folding of the protein (Chen et af., 1990; Denning et af., 1992). Such proteins get rapidly identified by a “quality control” mechanism that leads to their degradation from the endoplasmic reticulum preventing their progress through the Golgi and on to the apical plasma membrane (Hurtley and Helenius, 1989).Reduction of temperature results in the appearance of cyclic AMP-regulated chloride channels in the plasma membrane that have the same conductance and I-V relation as the wildtype protein but with a lower open probability. These findings suggest that the mutant CFTR is not present in the Golgi. This might explain why the Golgi is abnormally acidified in cystic fibrosis. We found that this defective acidification is accompanied by dramatic changes in Golgi function (Barasch et af., 1991). There is a widespread decrease in sialylation of membrane and secreted proteins. Because sialylation and sulfation are competitive in the Golgi, it is likely that this defect in sialylation provides an explanation for the increased sulfation. Because there is also a defect in glycosphingolipid sialylation, we had proposed that the greater amount of asialogangliosides could act as receptors for Pseudornonas organisms, a major cause of morbidity and mortality in CF. One puzzling finding is that CF cells demonstrate abnormalities in two other channels. The amiloride-sensitive Na channel is tonically open (Willumsen and Boucher, 1991). An outwardly rectifying CI channel (ORCC)
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is present in CF cells but it cannot be regulated by protein kinase A (PKA) (Schoumacher et al., 1987; Welsh and Liedtke, 1986); transfection with the wild-type CFTR corrects this defect (Egan el al., 1992). Because the mutant and wild-type CFTR have essentially the same electrophysiological characteristics (except for open probability), it is likely that the ORCC is a different protein. Since the outward rectifier exhibits defective regulation in CF cells, we can conclude that when CFTR does not leave the endoplasmic reticulum abnormalities in other proteins can result. As far as we know, p64 is not directly involved in CF. The protein exists in CF epithelial cells and does not seem to have either an abnormal location or molecular weight, in that none of these parameters are changed when the cells are transfected with the wild-type CFTR. However, it remains possible that p64 is the outward rectifier channel and we are now attempting to reconstitute the overexpressed protein in order to test this question. II. THE IAA-SENSITIVE CHLORIDE CHANNEL A. Purification and Reconstitution
Using bovine kidney cortex we isolated membranes that were depleted of brush borders but contained a variety of light intracellular organelles and some basolateral membranes. Using this preparation we developed an assay based on loading the vesicles with KCI and passing them down an anion exchange resin. Vesicles that had CI but no significant K conductance will develop a membrane potential, positive inside. Addition of extracellular 36Clleads to the accumulation of the tracer in only the vesicles that have a CI channel. Using this assay we screened a large number of potential inhibitors and found that the indanyl oxyacetic acids are reasonable inhibitors with an IAA-94 being the most potent in this system. The K i in the bovine kidney cortex vesicles was in the range of 1-2 p M (Landry e f af., 1987). Subsequent studies by others showed that the potency in other systems was weaker. We constructed an IAA-23 affinity resin and developed a simple procedure for solubilization and reconstitution of CI channel activity from bovine kidney cortex membranes. Solubilized material was adsorbed to the affinity resin and washed extensively. Exposure of the column to 100 p M IAA-94 resulted in the elution of four proteins of 29, 40, 64,and 96 kDa. As seen in Fig. l A , the 29- and 40-kDa proteins were the most abundant. Excess phospholipids were added and the protein:lipid mixture was dialyzed extensively to remove the IAA-94 and detergent. The resultant
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FIGURE 1 (A) Silver-stained gels of proteins purified from solubilized bovine kidney cortex vesicles using the IAA-23 column. (B) lmmunoblots using antibodies generated against 64-kDa proteins cut from gels similar to those in panel A. (C) Immunoprecipitation using the antibodies described in panel B; after elution of the proteins from the antibody beads they were biotinylated and probed with avidin.
proteoliposomes were used for reconstitution experiments. It became clear that the phospholipid vesicles had a 3hCluptake that was independent of protein content. Toyoshima and Thompson (1975) had previously found that phospholipids act as a CI:CI exchange system. To overcome this problem we co-reconstituted the purified proteins with bacteriorhodopsin, a light-driven proton pump. When these vesicles were exposed to light they developed a membrane potential, positive inside. This energized the uptake of 36CI into these vesicles by a potential-driven, i.e., channelmediated, mechanism. In the presence of potassium, addition of the electrogenic ionophore, valinomycin, led to the collapse of the membrane potential and reduction of the uptake of 3bC1to the basal level. Quantitative analysis suggests that the affinity column has resulted in a minimum of a 1000-fold purification. Which of the four protein was the C1 channel was not clear. Indeed, it could be that the purified CI channel was in such low
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abundance that it was not visible in the silver-stained gels. We purified larger amounts of the proteins and were able to obtain N-terminal sequences on the 29- and 96-kDa protein. They turned out to be glutathioneS-transferase and Na,K-ATPase, respectively. Both of these proteins are known to bind to ethacrynic acid, the parent compound of IAA-94; hence, this explains why they were purified with an IAA-23 column.
B. p64, a Component of the IAA-Sensitive Cl Channel in Kidney and Other Cells
To identify which of the remaining proteins were components of the CI channel we "scaled up" the preparation and separated the purified proteins on SDS-PAGE. The 64- and 40-kDa bands were cut and injected into guinea pigs. Only the 64-kDa bands generated useful antibodies. These antisera recognized a 64-kDa band in kidney vesicles (Fig. IB). Immunoblots of membranes from a variety of cell types in a variety of species, including plants, also yielded bands in the 60- to 70-kDa range. It was surprising to see that the antibody recognizes the protein across such a wide species range. All cells examined had the protein expressed in them. However, the protein was expressed in low abundance such that positive immunoblots were seen frequently only after membranes were used rather than cell lysates. Immunocytochemistry did not reveal any staining except in CF-PAC, a pancreatic adenocarcinoma cell line established from a patient with cystic fibrosis. In that cell, there was staining in perinuclear (Golgi?) vesicles and some of the cells showed staining in the apical cell membrane (Fig. 2). To demonstrate that the antigen for this antibody is a component of a CI channel we performed immunodepletion experiments. We solubilized kidney cortex vesicles and incubated them with preimmune, immune, and no immunoglobulins. The antigen-antibody complexes were precipitated with protein A beads and the supernatants were reconstituted and assayed for voltge-sensitive 36C1uptake. The material incubated with no Ig or with preimmune Ig exhibited vigorous valinomycin-sensitive uptake. Preincubation with anti-p64 sera led to a complete removal of any C1 channel activity in the reconstituted proteoliposomes. To provide further evidence that p64 was a necessary component of the IAA-sensitive C1 channel we partially purified Cl channel activity by separating solubilized kidney cortex vesicles on a gel filtration column. The column effluent fractions were reconstituted. Valinomycin-sensitive 36Cluptake was present only in the 400- to 550-kDa fraction. When these fractions were stained by anti-p64
3. IAA Vacuolar Chloride Channel
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FIGURE 2 lmmunocytochemistry of permeabilized CF-PAC cells using the anti-p64 antibody.
antibodies, only those fractions that contained p64 showed reconstitutable 36C1uptake (Redhead et al., 1992). These results provide strong evidence that the antigen recognized by anti-p64 antibody is an important component of a CI channel. That reconstitutable activity traveled at such a high M , suggests that this CI channel complex is either composed of several copies of p64 or composed of a heteromultimer (Fig. 3 demonstrates these results using an antibody against the cloned p64 described below). C. Cloning of the p64 cDNA
We initially searched several cell lines and tissues to identify one that overexpressed p64 and found that kidney cortex showed the highest abundance. We emphasize, however, that even in the kidney p64 is a lowabundance protein. We constructed an expression cDNA library using standard methods and screened it with anti-p64 antisera. Several positive clones were identified and the one which had the longest insert, termed H2B, was analyzed in detail. H2B was used for Northern analysis, where it showed that the kidney expresses a 6.3-kb message, as well as other
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FIGURE 3 (A) Bovine kidney cortex vesicles were solubilized with octyl glucoside and passed on a gel filtration column. The effluent was divided into four fractions and the protein content was measured in each fraction. Equal amounts of protein were revconstituted into asolectin phospholipids and '6CI uptake was measured in the presence and absence of valinomycin a s described previously (Redhead ef a!., 1992). Each fraction was analyzed by SDS-PAGE and immunoblots using an antibody that was affinity purified against the fusion protein H2B. (B) Anti-pM antibodies were affinity purified against the fusion protein H2B and the resultant antibodies were incubated with solubilized kidney cortex vesicles. The control antibodies were the same anti-p64 antibodies "affinity purified" against the same region of E. coii lysates using bacteria transfected with the vector lacking the H2B insert. Immunodepletion experiments are described in the text.
shorter messages. We identified overlapping clones and using the polymerase chain reaction we were eventually able to obtain a full-length sequence of the cDNA. There was an open reading frame that codes for a protein of 437 amino acids with an M,of 49,008 (Fig. 4) (Landry et al., 1993). Neither the nucleotide nor the predicted amino acid sequence of p64 bear significant homology to any known gene or protein. The deduced amino acid sequence is markedly rich in acidic residues and has a predicted PI of 4.14. A hydrophobicity analysis of the predicted amino acid sequence
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by the method of Kyte and Doolittle showed that there are at least two potential transmembrane domains at amino acids 201 -236 and 367-385. No putative signal sequence was discerned, suggesting that the N-terminus of the protein would be predicted to be in the cytoplasm. This large section of the protein contains consensus sequences for phosphorylation by protein kinase C, tyrosine kinase, and casein kinase 11. An octapeptide sequence with a high density of negatively charged amino acids [in single letter code, Q(E,A, or G)SD(P or S)EEP] is repeated four times, and partially for a fifth, in this first intracellular domain. There is no significant homology to this specific sequence motif in the data base except for heavily negatively charged proteins. A more focused search regarding calcium binding proteins did not result in any similarity to this motif, and in particular the motif is not homologous to an E-F hand sequence. One possibility is that it represents a site of protein-protein interaction. The sequence between the two putative transmembrane domains is predicted to be extracellular and it contains one potential N-glycosylation site. The C-terminus of the protein is predicted to contain the second intracellular domain and contains a single consensus sequence for protein kinase A phosphorylation at S435. We generated a @-galactosidase-H2B fusion protein of about 70 kDa in Eschevichia coli and affinity-purified anti-p64 antibodies over the fusion protein. These antibodies recognized a 64-kDa protein in kidney cortex and other cells as well as recognized partially purified (by gel filtration) CI channel proteins. To demonstrate that H2B protein is also a component of the IAA-sensitive Cl channel we performed another immunodepletion experiment as described above. We found that anti-H2B antibodies depleted valinomycin-sensitive 36Cl uptake. These results suggest that we have cloned a CI channel protein (Fig. 4). RNA from bovine kidney cortex, skeletal muscle, and heart had a relatively abundant transcript, at approximately 6.5 kb, which hybridized with p64 cDNA. A transcript of the same size was also seen in lower amounts in kidney medulla and adrenal. All tissues examined had two distinct smaller transcripts at approximately 5.5 and 4.5 kb. In addition, kidney medulla, adrenal, and brain have a 7-kb transcript and the heart has a smaller transcript of about 2 kb. This diversity of transcript size in various tissues suggests that this gene is subject to alternate splicing or that a family of closely related genes exist. RNA from the human chloride transporting epithelial cell lines T84 and Panc 1 had a single major transcript of approximately 5.5 kb which hybridizes to the p64 probe at high stringency. RNA from the shark rectal gland, a chloride-secreting epithelium rich in chloride channels, contains transcripts of approximately 4 and 6 kb that hybridize with the p64 probe at moderate stringency.
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clone 11 B clone H2B
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S E G N E S A S A S P E N L F V K A G 208 7 2 1 tcagaaggaaacgaatcggcttccgcaagccccga ttaacctctttgtgaaggctgga I D G E S I G N C P F S Q R L F M I L W 228 7 8 1 atcgatggtgaaagcattggcaactgtcccttctctcagcgtctctttatgatcctctgg T
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FIGURE 4 (A) Partial restriction map of H2B. (B) Complete nucleotide and predicted amino acid sequence of H2B. (C) Kyte-Doolittle hydropathy plot of H2B.
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t
gaaggactc~accgtctcc~caaggactctggcttcaca~acttctcttccacgccacct ctggaaacttctgtctctatcaggccacatctctctggcatccttgtaacccccccgcct gctggctttgaccaaagtcagcgccatctccctctggtcaggcaggaatcccgcaagcag aaaagagaqaaacggtcaagctgtcagcctttcggacctggactgggttccgtgtgtttg
ggggtcggtgccggggggaaccctgtctgtgggattgtcactgqccccttttgccaatat tgaaatatctcctgagatgcattagaaacctacaacatgctgtccttatccacccctcct ctttgtcagtaactccaaggccaaacgccctcttcgttcttattagaaagaggtgcatgg
ctgtgttagtgga acagagagtggatggggcagacgtgggtctgggcacgtggcagaca cacctccagtcac~cagcactttctagcattgtcacttcgggcactgaaggccagattgg aaaacaacttcagacagtctcagttttctgcagtgctgggcacagtctgatgtgatcaca tacctggcttgatgctgatctctattatctgtccagaccttgccaggaagggaaattggc
atgccattccaaactggggtacctggggaggggaggggaggggagaagtgttgatgccaa aaggcccgtggggtctaccagccatggggtttgcttgcttatgggagtggtttcattgga
gattacatgcctgagtttgactatgtttatccacggttgaattttggtctctgagaaagc agatgg9agtgtg9999gt999999at9gatgcagga99ctaagaa9acctttgtat9a9 gctcagtgttccctgggaatcttctagataqatcttttctcttatgatctaagtctcgaa
ccagtgatgtcatgtagctgccatcttcatagcaaaataccaacaattgaccaaaaatga
aaaaaaa FIGURE 4
~'~J!lfitlift'd
70
Qais Al-Awqati
D. p64 Is Not Targeted to the Plasma Membrane of Nonepithelial Cells but in Epithelial Cells It Is Located in the Apical Plasma Membrane
p64 was present at the RNA and protein level in all cells tested. To examine its distribution we biotinylated the surface of confluent monolayers of epithelial cells such as MDCK and two nasal polyp cell lines, one obtained from a normal subject and the other obtained from a patient with cystic fibrosis. The cells were solubilized and the biotinylated proteins were precipitated with avidin beads and washed extensively. The proteins were then analyzed by immunoblots using an anti-p64 fusion protein antibody. All these epithelial cell lines had p64 present on their apical membranes. However, when similar studies were performed in three nonepithelial cell lines, 3T3 fibroblasts, COS cells (monkey kidney fibroblatoid cell line), and Sf 9, insect ovary cells, there was no p64 on the surface. Membranes isolated from these cells had p64 in them. We also injected RNA transcribed from the T7 promoter construct of the full-length clone into Xenopus oocytes. No new plasma membrane chloride current appeared on electrophysiological studies. However, a new protein with the appropriate molecular mass appeared in microsomes and was unable to be targetted to the plasma membrane. Biotinylation of the surface membranes of oocytes failed to show the presence of the endogenous or exogenous p64. In addition p64 was overexpressed in Sf 9 cells using a baculovirus system. The results shows that the protein is expressed at very high levels. However, it does not reach the surface. Heterologous expression in COS cells also did not lead to targeting of the protein to the surface. These results demonstrate that p64 either contains a “retention” signal in nonepithelial cells or it requires an accessory protein to target it to the plasma membrane. Because our studies have identified the presence of several transcripts that cross-hybridize with p64 probes, it is possible that a family of transcripts exists some of which are targeted to the plasma membrane while others are retained in intracellular organelles. If all p64 transcripts are similar then the epithelial targeting of p64 must require another protein whose function is similar to “molecular chaperones.” Studies have identified a group of proteins which direct the targeting of other membrane proteins to their final destination. A mutation in Drosophila, ninaA, results in the retention of one of the rhodopsin proteins in the endoplasmic reticulum (Colley et af., 1991). This protein is a resident protein of the ER and is a membrane protein with a large cytoplasmic domain. The cytoplasmic domain is homologous to proteins that bind FK506, the cyclosporin homolog. Since this class of proteins,
3. IAA Vacuolar Chloride Channel
71
the cyclophilins, also catalyze cis trans isomerization of prolines, it has been suggested that they are involved in proper folding of their substrates. The surprise is that none of the other rhodopsins in Drosophila is affected, suggesting that each rhodopsin molecule might have its own folding facilitator. A yeast protein, SH2, has been identified which promotes correct targeting of many amino acid transporters to the plasma membrane (Ljungdahl ct al., 1992). When this protein is inactivated, these polytopic membrane proteins are retained in the ER in an improperly folded manner.
Acknowledgments The work reported here was supported by grants from NIDDK and the Cystic Fibrosis Foundation.
References Al-Awqati. Q. (1986). Proton translocating ATPases. Annrc. Rev. Cell Biol. 2, 179-199. Barasch. J.. Gershon. M. D.. Nufiez, E. A.. Tamir. H.. and Al-Awqati, Q. (1988).Thyrotropin induces the acidification of the secretory grades of parafollicular cells by increasing the chloride conductance of the granular membrane. J . Cell Biol. 107, 2137-2147. Barasch. J.. Kiss, B.. Prince, A.. Saiman. L.. Gruenert. D.. and Al-Awqati. Q. (1991). Defective acidification of intracellular organelles in cystic fibrosis. Nntctrr (London) 352, 70-73. Chen. S . H.. Gregory, R. J.. Marshall, J., Paul, S . . Souza, D. W., White. G. A., O'Riordan, C. R.. and Smith, A. E. (1990). Defective intracellular transport and processing of CFTR is the molecular basis of most cystic fibrosis. Cell (Cambridge, Mass.) 63, 827-834. Colley, N. J., Baker, E. K., Stamnes, M. A., and Zuker, C. S. (1991). The cyclophilin homologue. ninaA is required in the secretory pathway. Cell (Cambridge, Mass.) 67, 255-263. Denning. G. M., Anderson, M. P.. Amara, J. F., Marshall, J.. Smith, A. E., and Welsh, M. J. (1992). Processing of mutant CFTR is temperature sensitive. Nature (London) 358, 761-764. Egan, F., Flotte. T.. Afione, S., Solow, B., Zeitlin, P. L., Carter, B. J., and Guggino, W. B. (1992). Defective regulation of an outwardly rectifying CI channels by protein kinase A corrected by insertion of CFTR. Nature (London)335/338, 581-584. Glickman. J., Croen, K., Kelly, S . , and Al-Awqati, Q. (1983). Golgi membranes contain an electrogenic H' pump in parallel to a chloride conductance. J . Cell Biol. 97, 1303-1308. Hurtley, S. M.. and Helenius, A. (1989). Protein oligomerization in the endoplasmic reticulum. Annu. Rev. Cell Biol. 5 , 277-307. Landry. D. W.. Reitman. M., Cragoe. E. J., Jr., and Al-Awqati. Q. (1987). Epithelial chloride channel. Development of inhibitory ligands. J . Gen. Physiol. 90, 779-798. Landry. D. W.,Akabas, M. H.. Redhead, C., Edelman, A.. Cragoe. E. J., and Al-Awqati. Q. (1989). Purification and reconstitution of chloride channels from kidney and trachea. Science 244, 1469-1472. Landry. D. W., Sullivan, S . , Nicolaides, M., Redhead, C., Edelman. A,. Field, M., Al-Awqati, Q., and Edwards, J. (1993). Molecular cloning of p64, a chloride channel protein. J . Biol. Chem. 268, 14948-14955.
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Ljungdahl. P. 0.. Gimeno, C. J . . Styles. C. A.. and Fink. G. R . (1992). SH3: A novel component of the secretory pathway specifically required for localization of amino acid permeases in yeast. Cell (Cambridge, Mass.) 71, 463-478. Olsen. R. W.. and Tobin. A . J . (1990). Molecular biology of GABA, receptors. FASEB J . 4, 469-1480. Paulmichl. M., Li, Y.. Wickman. K.. Ackerman. M., Peralta, E.. and Clapham. D. (1992). New mammalian chloride channel identified by expression cloning. Nurirre (London1 356, 238-241. Ran. S . . and Benos. D. J . (1991). Purification and reconstitution of a chloride channel from tracheal membranes. J . B i d . Chen?. 266, 4782-4788. Redhead, C. R.. Edelman. A., Brown, D.. Landry. D. W.. and Al-Awqati. Q. (1992). A ubiquitous 64 kDa protein is a component o f a chloride channel of plasma and intracellular membranes. Proc. Natl. Acad. Sc,i. U . S . A . 89, 3716-3720. Riordan. J . R . (1992). The molecular biology of chloride channels. Crtrr.. Opir7. Nrphrol. ff.vpertens. 1, 35-42. Schoumacher, R. A.. Shoemaker. R. L., Halm. D. R.. Tallant. E. A.. Wallace, R . W., and Frizzell. R. A. (1987). Phosphorylation fails to activate chloride channels from cystic fibrosis airway cells. Nature (London) 330, 752-754. Steinmeyer. K., Ortland, C.. and Jentsch. T. J. (1991). Primary structure and functional expression of a developmentally regulated skeletal muscle chloride channel. Narrrw (London) 354, 301-304. Toyoshima. Y.. and Thompson. T . E. (1975). Chloride flux in bilayer membranes: The electrically silent chloride flux in semispherical bilayers. Biochernisrry 14, 1525. Weiss. M . S . . and Schulz. G. E. (1992). Structure of porin refined at 1.8 A resolution. J . Mol. B i d . 227, 493-509. Welsh, M. J . . and Liedtke, C. M. (1986). Chloride and potassium channels in cystic fibrosis airway epithelia. Nature (London)322, 467-470. Welsh, M. J., Anderson, M . P., Rich, D. P.. Berger, H. A.. Denning, G. M., Ostergaard. L. S., Sheppard, D. N., Cheng, S. H.. Gregory, R. I.. and Smith. A. E. (1992). CFTR: A chloride channel with novel regulation. Neuron 8, 821-829. Willumsen, N. J., and Boucher, R. C. (1991). Na transport and intracellular Na activity in cultured human nasal epithelium. Am. J . Physiol. 261, C319-C331.
CHAPTER 4
Anion Channels in the Mitochondria1 Outer Membrane Marco Colombini Laboratories of Cell Biology. Department of Zoology, University of Maryland, College Park, Maryland 20742
I. Introduction 11. Basic Properties 111. Molecular Structure A. Composition B. Pore Size C. Secondary Structure D. Structure of the Open State IV. Structure from Electron-Microscopic Imaging A. Negative Staining B. Freeze-Drying and Shadowing C. Freeze-Fracturing and Shadowing D. Freezing in Vitreous Ice E. Two Surfaces of the Crystal F. Structure of the Open and Closed States V. The Voltage-Gating Process VI. The Properties of VDAC Can Be Tuned and Modulated A. Osmotic Pressure B. The VDAC Modulator C. Ultrasteep Voltage Dependence D. Donnan Potential E. Aluminum Inhibition F. NADH-Induced Increase in Voltage Dependence VII. Function VIII. Prospects References Ciwrenc Topics in Membranes, Volume 42 Copyright 0 1994 by Academic Press. Inc. All rights of reproduction in any form reserved.
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Marco Colombini
74 1. INTRODUCTION
The notion that the outer mitochondrial membrane contains channels does not raise eyebrows these days when patch clamping of most cell membranes reveals some sort of channel(s). However, when first observed in 1975, the reconstitution of an anion-selective channel from mitochondria was a surprise (Schein et al., 1976). By hindsight, the existence of large channels in the outer membrane favoring anions fits nicely with the major function of mitochondria, energy transduction. Substrates and products are mostly negatively charged molecules: pyruvate, ADP. ATP, phosphate, etc. These must cross the outer membrane at rather high rates in order to supply the energy needs of an active, rapidly respiring cell. From the early experiments that demonstrated that mitochondria were composed of two layers of membranes (Werkheiser and Bartley, 19571, the evidence indicated that the outer membrane was not merely ‘‘leaky’’ but permselective. Standards of membrane intactness used for other systems did not apply to the outer membrane. Its demonstrated permeability to sucrose did not indicate membrane damage because dextrans and cytochrome C were impermeant if mitochondria were isolated with care (Werkheiser and Bartley, 1957; Wojtczak and Zaluska, 1969). This and electronmicroscopic evidence indicated the presence of large channels in the outer mitochondrial membrane (Parsons et al., 1965). The reconstitution into planar phospholipid membranes of large voltagegated channels, called VDAC (voltage-dependent anion-selective channel), indicated that these channels were not static structures but dynamic and under regulation (Schein et al., 1976; Colombini, 1979). The voltage dependence of the channels is steep and not unlike that responsible for the electrical excitability of nerves, muscles, and other cells. Although still unmeasured, an electrical potential across the outer membrane capable of altering VDAC’s conformation is not only possible but highly likely. Unless the colloidal charge in the intermembrane space and the cytoplasm are identical, a nonzero Donnan potential must exist. Its value could be easily altered by protein phosphorylation or local changes in pH or free [Ca2 1. The importance of VDAC and its properties to mitochondrial function is strongly indicated by the remarkable conservation of its structure and functional properties (Colombini, 1989). The discovery of new regulatory mechanisms (Holden and Colombini, 1988) and their remarkable conservation (Liu and Colombini, 1991) provides further evidence for an important and elaborate regulatory system. +
4. Outer Mitochondria1 Membrane Channels
75
II. BASIC PROPERTIES VDAC channels form highly conductive pathways (4 to 4.5 nS in I M KCI) in phospholipid membranes (Colombini, 1979,1989).An example of VDAC channels from rat liver inserting into planar phospholipid membranes (Fig. I ) shows their uniformity. These reflect a large aqueous pore whose radius in the high-conducting (open) state is estimated at 1.2 to 1.5 nm (see below). This pore allows inulin, polyethylene glycol (PEG) 3400, and dextran 2000 to cross the membrane and excludes PEG 6800 and dextran 8000 (Colombini, 1980a,b; Zalman et al., 1980).The channels are quite stable and long-lived in the open state at low membrane potentials. Raising the potential to either positive or negative values causes VDAC to enter low-conducting states termed "closed" because there is evidence that they are essentially impermeable to important metabolites (see below). Each channel can therefore undergo two separate voltage-
50 T L
40--
9
30--
v
8 m
c
0
Conductance (nS)
U
5
0
20--
FIGURE 1 Single VDAC channels, isolated from rat liver mitochondria, inserting into planar phospholipid membranes. The increments in membrane conductance (see inset) are clustered at about 4.5 nS (medium was 1 M KCI. 5 mM C a Q : the applied voltage was 10 mVI. Smaller increments are due to substates.
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Marco Colombini
dependent structural changes, one at positive potentials and the other at negative potentials. The situation is more complex, however, because there exists a family of closed states at both signs of the potential. the significance of which is unclear (Colombini, 1980b,1986). With higher applied potentials and following special treatments (Colombini et d., 1987; Holden and Colombini, 1988; Liu and Colombini, 1992a).VDAC channels can be induced to enter states with extremely low conductances. Some look at VDAC closure as an inactivation process because the channels “adapt” with time to the closed state. The rate of channel opening depends on the length of time they have been held in a closed conformation by means of an electric field. This molecular memory may be important in long-term changes in mitochondria1function that may be induced by VDAC closure. With respect to the study of VDAC’s electrophysioiogical properties, this memory is simply a nuisance. VDAC channels are not absolutely selective for anions over cations but a clear preference exists (Colombini, 1980b). This preference is seen even with small ions capable of traveling through the channel at some distance from the protein walls. K C and CI- have almost the same mobility in water but CI- can be selected by over 4 : I depending on the ionic conditions (Fig. 2). As the size and charge of the ion increases, the selectivity for the anion should increase for ions of comparable size and absolute charge. For example, VDAC is more permeable to the doubly negatively charged
92 E
4
LCT
........ GHK 1
10
1
Activity Ratio FIGURE 2 The reversal potential of VDAC channels from N . crassa reconstituted into planar membranes. The activity of KCI was 0.06 in the low-salt side. The data are indicated by the triangles (mean 5 SD) and the theoretical fits are the solid line (large-channel theory; Zambrowicz and Colombini. 1993) and dotted line (Goldman-Hodgkin-Kaz equation).
4. Outer Mitochondria1 Membrane Channels
77
calcium-EDTA complex than it is to the much smaller doubly positively charged calcium ion ( M . Colombini, unpublished observation). 111. MOLECULAR STRUCTURE
A. Composition
VDAC channels whose genes have been cloned from mammalian and fungal sources (or the protein sequenced) range in molecular weight from 30k to 32k. So far they fall into two categories: those composed of 282 amino acids (after removal of the N-terminal methionine; Mihara and Sato, 1985; Kleene et al., 1987; Kayser ef al., 1989) and those with an 1 1 amino acid extention beyond the N-terminal methionine (as deduced from the nucleotide sequence; Bureau et al., 1992; Blachly-Dyson et al., 1993). These may be referred to as VDACl and VDAC2 following the terminology introduced by Blachly-Dyson et 01. (1993). However, estimates of polypeptide molecular weight based on SDS-PAGE vary between 29k and 37k (De Pinto and Palmieri, 1992; Bureau et al., 1992; Blumenthal et (11.. 1993) depending on the source of the material. The rat version of VDAC2 forms a band at 36k on SDS-PAGE indicating possible glycosylation (Bureau et ul., 1992) or anomalous mobility. Perhaps these effects account for the variability in molecular weights (measured by SDS-PAGE) of VDAC from the different sources although other VDAC gene families may exist (Mike Forte, personal communications). However, the rat protein just mentioned is reported to interact tightly with the GABA receptor and its role in this interaction is the subject of interesting speculation. The proposed plasma-membrane association of this gene product supports previous reports of VDAC channels located on the surface membrane of animal cells (Blatz and Magleby, 1983; Nelson et al., 1984; Thinnes, 1992). Despite VDAC’s symmetrical behavior (e.g., voltage-dependent channel closure at both positive and negative membrane potentials) strong evidence now favors the conclusion that each VDAC channel is formed by one 30-kDa polypeptide. Estimates of protein present in two-dimensional crystals of VDAC from Neurospora crassu viewed as frozen-hydrated specimens indicated that the mass per channel-forming unit might be less than needed for a dimer (Mannella, 1986,1987). Mass measurements (Thomas et al., 1991) based on scanning-transmission electron microscopy of the same kind of two-dimensional crystals of VDAC yielded a mass per unit area of crystal of 1.9 kDa/nrn’. Since, on the average, one channel occupies an area of 23 nm3, the mass of matter per channel is 44 kDa. Thus there is insufficient mass for a dimer and the results are consistent with a 32% lipid content in the crystal. Further support for the monomer
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Marco Colombini
hypothesis came from work with VDAC mutants expressed in yeast (Peng rt NI., 1992b). The mutants chosen were some of those (see below) that had been shown to alter VDAC's selectivity by changing the charge on the protein walls of the aqueous pore. If two polypeptides contributed to the walls of the pore then the selectivity of the resulting channel would depend on charged residues from both polypeptides. Thus the measured selectivity of an individual channel should be an average of the contributions of each polypeptide. A dimer therefore raises the possibility of hybrid channels. By introducing a plasmid containing a yeast VDAC sequence containing two point mutations that change the reversal potential of VDAC by 10 mV into a yeast cell containing the wild-type VDAC gene, Peng and co-workers tried to obtain hybrid channels, i.e., channels whose selectivity was half way between that of the wild-type VDAC and that of the purely mutant form. The selectivity of individual VDAC channels isolated from this yeast strain revealed only channels with either pure wildtype selectivity or pure mutant selectivity (Fig. 3). A sufficient number of channels was examined such that the probability of missing a hybrid (if such existed) was less than 1 in 10'. The authors repeated the whole experiment with a different mutant VDAC gene with the same results. Thus, these experiments on functional VDAC channels from yeast agree with the electron-microscopic experiments with N . crassa VDAC. Each VDAC channel is most likely composed of one and only one 30-kDa polypeptide. Early work indicated that detergent-solubilized VDAC was a multimer of 30-kDa polypeptides (Linden and Gellerfors, 1983). This, taken together with the observation that the number of channels inserting into a planar phospholipid membrane was linearly related to the amount of detergentsolubilized VDAC added to the aqueous phase (Colombini, 1980b; Roos et af., 1982), indicated that one VDAC channel was composed of two 30-kDa polypeptides. A reexamination of the data shows that in deducing the molecular weight of VDAC from its sedimentation rate, Linden and Gellerfors did not consider the contribution to the overall mass of the water in the pore. This and tightly bound sterol may account for some of the mass attributed to protein. Further evidence that VDAC is a monomer comes from indications that the protein is inherently asymmetric in intact mitochondria (De Pinto and Palmieri , 1992). B. Pore Size
VDAC's pore size has been estimated in a variety of ways each with its own drawbacks. A trivial approach is to simply use the single-channel
4. Outer Mitochondria1 Membrane Channels
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Reversal Potential (mV) FIGURE 3 Results of attempts to generate hybrid VDAC channels by expressing both wild-type and mutant VDAC genes in yeast. Reversal potentials were measured on single VDAC channels in the presence of a 10-fold gradient of KCI. The bars show the expected probability of observing reversal potentials characteristic of wild-type, mutant, and the intermediate hybrid channel. The circles represent all the measured reversal potentials. In two sets of experiments with different mutant genes (indicated in the figure) no channels with intermediate reversal potentials were observed.
conductance and calculate the radius of a cylinder of solution (whose length is the thickness of the membrane) that would yield the same conductance. This approach has been shown to yield poor estimates for channels of known pore radius. For example the conductance of gramicidin is two times greater than that of nystatin (12 pS vs 6 pS in 2 M KCI) even though its pore radius is two times smaller (0.2 nm vs 0.4 nm) (Holz and Finkelstein, 1970; Kasumov et al., 1979; Finkelstein and Anderson, 1981). However, for large channels this approach should yield better estimates since the solution in the channel should behave more like bulk solution. One must, however, at least perform the obvious correction for access resistance. This type of calculation leads to a pore radius of 1 .O nm. Another approach to estimating the pore radius is to determine the size of the largest nonelectrolyte that can permeate through the pore
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Marco Colombini
(Colombini, 1980a,b). VDAC was shown to be permeable to inulin and PEG 3400 but not permeable to PEG 6800. The Stokes-Einstein radii of the permeants are 1.4 and 1.9 nm, respectively (Scherrer and Gerhardt, 1971). Thus the pore radius was estimated to be 2 nm. The flexibility of these nonelectrolytes may allow them to deform resulting in permeation through narrower openings. Thus the 2-nm estimate is likely an overesti mate. Electron micrographs of negatively stained two-dimensional crystals of VDAC reveal (after computer filtration and averaging) an array of stainfilled pores. An estimated pore radius is 1.2 to 1.5 nm (Mannella et al., 1992). This technique has been used with various negative stains including phosphotungstic acid, uranyl nitrate, and aurothioglucose yielding comparable results. Drawbacks to this approach are positive staining, which would overestimate the size of the pore; grain size, which could underestimate the size of the pore keeping the stain away from the wall; and orientation of the stain, in the case of aurothioglucose, which could underestimate the radius (the glucose could preferentially bind to the channel by hydrogen bonding at sites with no gold attached). A novel method was developed (Vodyanoy et al., 1992)to estimate the pore size based on the properties of the access resistance. When corrected for the size of the permeating ion, the estimate is 1.2 nm. This approach relies on a macroscopic understanding of the nature of the relationship between pore radius and access resistance that may not apply exactly to structures as small as channels. Perhaps a good estimate is in the range of 1.2 to 1.5 nm. However, considering the strong evidence that amino acid side chains extend into the channel from a p-sheet wall (Blachly-Dyson et al., 1990), the exact physical size of the pore is, in fact, ill-defined. Most important is the conclusion that VDAC is large enough to allow metabolites the size of ATP to cross the outer membrane.
C. Secondary Structure VDAC’s fundamental properties are highly conserved in mitochondria isolated from all eukaryotic kingdoms (Colombini, 1989). This requires a fundamental conservation of protein structure. However, measuring structural conservation based on primary sequence and antibody crossreactivity reveals marked changes in the structure over time (De Pinto and Palmieri, 1992).There is a 24% conservation in the primary sequence between yeast and human sequence (Kayser et al., 1989) and only 43% conservation between two fungi, S . cereuisiae and N . crassa (Kleene ef
81
4. Outer Mitochondria1 Membrane Channels
al., 1987). Remarkably, however, the number ofamino acids in the protein is identical for VDACl from fungi and the human (282 amino acids after removal of the N-terminal methionine). Most importantly. the pattern of VDAC’s secondary structure is highly conserved (Fig. 4; Colombini et uf.,1992). It is this pattern of VDAC’s secondary structure that is believed to be the key to VDAC’s structure and function. VDAC’s unusual structure required a different method of analysis than that normally used for membrane proteins, The large size of VDAC’s pore and small mass of protein per channel require a thin protein wall, probably one layer of protein. This protein wall must have a polar surface facing the aqueous pore and an apolar surface facing the hydrocarbon tails of the phospholipids, Examinations of the primary sequence reveal amino acid stretches that would have the appropriate character to form such a
30
20 10
0
I
.S. cerevisiae
20 10
-.
0
0
50
100
150
200
250
Beginning Residue Number FIGURE 4 Results of the analysis of the primary sequence of VDACl from three species. The hydropathy value of each group of 10 adjacent amino acids was summed after every second value was multiplied by - I . These values are plotted against the number of the first amino acid in the summation (starting at the N-terminus). The higher the peak the better the alternating polar-nonpolar pattern, and the more likely the sequence will form part of the wall of the VDAC channel.
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Marco Colombini
wall if the wall had a p structure. One such analysis (Blachly-Dyson et al., 1989) that looks for 10-amino acid stretches that contain alternating polar and nonpolar residues shows that the location of these segments in the primary sequence is remarkably conserved in the known VDAC sequences (Fig. 4). In the representation in the figure, the higher the peak the better the alternating pattern and thus the more likely the 10 amino acids following this point in the sequence are to form part of the wall of the channel. For yeast VDAC, the transmembrane location of all but one of the major peaks has been verified (see below). It goes without saying that natural selection tends to preserve the essential features of a protein to preserve the desired function. The high degree of interaction between the protein structure of VDAC and its environments (the two membrane surfaces, the aqueous pore, and the lipid bilayer) should provide constraints on the location of polar, charged, and nonpolar residues, but perhaps a weaker constraint on the packing of residues. This would explain the relatively low percentage of amino acid identity in the primary sequence and low antibody cross-reactivity. D. Structure of the Open State The amino acid stretches predicted to form the walls of the pore by analysis of the primary sequence were tested to determine if they, in fact, form this wall. The proposed transmembrane strands should form a /3 structure that would wrap around forming a barrel. Charged residues on the suspected transmembrane strands should all face the lumen side of the barrel and these residues should influence the channel’s selectivity. It was found (Blachly-Dyson et al., 1990) that substituting one of these charged residues with a residue of opposite charge altered the channel’s selectivity in a discrete and predictable manner (boxed residues in Fig. 5 ) . All but one of the predicted transmembrane strands showed the expected selectivity change. Charge substitutions on the remaining strand and on regions predicted to be outside the channel (facing the environment on one or the other membrane surface) had no effect on selectivity (circled residues in Fig. 5 ) . From these studies, a membrane-folding pattern for the open state of the channel can be put forward that is based on solid functional studies (Fig. 5 ) . It is significant that at the ends of the transmembrane strands one often finds residues that would be expected to break the pattern thus locking the strand in the membrane. These include proline residues and adjacent charged residues. There is also a high probability of finding aromatic residues close to the membrane surface. While strands linked together by short loop regions are likely to be adjacent, the sideby-side location of other strands has not been determined.
4. Outer Mitochondria] Membrane Channels
83
FIGURE 5 Proposed folding pattern of yeast VDAC in a phospholipid membrane. The N-terminal a-helix is followed by 10 /3 strands. If this sheet were rolled into a cylinder it would form the channel. The boxed residues influence channel activity in the open state and the circled residues do not. The shaded residues have a similar effect on the selectivity of the closed state.
The N-terminus of the VDAC sequence contains a stretch of 20 or so amino acids that form an amphipathic a-helix. This segment has been reported (Mihara and Sato, 1985) to contain the information necessary to target the protein to the mitochondrion. However, unlike many other leader sequences, the segment is not cleaved. Since one side of this putative a-helix is highly charged and the other is highly nonpolar, this could form a transmembrane strand forming part of the wall of the pore. While originally proposed to be located outside the membrane (Forte et al., 1987), site-directed mutation at two sites (Asp 15 and Lys 19) influenced the channel’s selectivity in a way consistent with a transmembrane localization (Blachly-Dyson et al., 1990). Thus, in Fig. 5 the a-helix is included as part of the wall of the pore. However, antibodies directed to the ahelical portion of VDAC can bind to the channel in mitochondria. This has been interpreted as evidence that the a-helix is located on the surface (De Pinto and Palmieri, 1992). This interpretation is complicated by evi-
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Marco Colombini
dence that the a-helix and four or five p strands move out of the channel upon voltage-dependent closure (see below). Thus it is possible that antibody binding is occurring on closed or partly closed channels. The size of the pore formed when these transmembrane strands are allowed to form a cylinder depends on the tilt of the strands. The original analysis proposed a 33" tilt (Forte et al., 1987). This seemed reasonable if a large number of 0 strands contributed to the wall of the channel (the original proposal was 19 strands). However, if a monomer forms the channel with 13 transmembrane strands, a 33" tilt produces an aqueous pore with a very small diameter. Thus, either more protein segments form the walls of the pore or the protein strands must be tilted more severely. Further testing on regions of yeast VDAC that might form transmembrane strands revealed no effect of charge changes on the channel's ion selectivity (Peng et al., 1992a).Thus other strand tilts were explored. Due to the restriction imposed by interstrand hydrogen bonding, ,6 strands should tilt in a quantized manner: O", -3O", -55", etc. A 55" tilt would result in a pore of the right size. The only endocytic protein channel whose structure has been solved by X-ray diffraction is porin from Rhodobacter capsulatus (Weiss et a / . , 1991). It forms a fl barrel with strands that tilt over a variety of angles. Thus while VDAC shows no homology with this channel, the tilt in VDAC may be more complex than the first-order theoretical expectations.
Iv. STRUCTURE FROM ELECTRON-MICROSCOPIC IMAGING The large size of VDAC's pore has facilitated imaging of the channel with the aid of the electron microscope. Large ordered arrays of VDAC channels in the outer membranes of fungal and plant cells have allowed detailed images to be produced through the use of computer filtration and averaging methods. Techniques have been developed (Mannella, 1982) to increase the size and number of these arrays in the isolated mitochondria1 outer membranes.
A. Negative Staining
Negatively stained arrays of channels yield high-contrast images of the channel's aqueous pore filled with electron-dense stain. The packing of channels in the array shown in Fig. 6 is typical but can vary somewhat with conditions of preparation (Mannella et al., 1983). The packing of the channels is not what one might expect from simple cylinders. The
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FIGURE 6 An image of an array of VDAC channels from N . crussn after negative staining. The channels were in a large 2D crystal. The image was subjected to computer filtration and averaging. (Unpublished work of Lorie Thomas.)
crystallographic repeating unit contains six channels but that does not define the functional repeating unit. The first investigator to observe this chose the six channels adjacent to each other to be the repeating unit (Mannella, 1982). However, more recent observations indicate that the repeating unit may be centered in the region of low electron density (light regions in Fig. 6). Thus the functional repeating unit may be the six stainfilled pores around the island of low density. These structures could then pack in a hexagonal fashion to yield the observed pattern.
Marco Colombini
B. Freeze-Dying and Shadowing Detailed images obtained with specimens that were rapidly frozen, dried, and shadowed with platinum (Fig. 7) show the six channel openings surrounding an elevated central area that corresponds to the low-density region in the negatively stained images. The elevated region may correspond to protein domains coming from each of the six channels (see also
FIGURE 7 Images ofthe surface structure of VDAC arrays after freeze-drying. Electron micrographs, such as those shown on the left, were used to generate the averaged and filtered images on the right. (A and B) The two surfaces of the VDAC 2D crystals formed in the outer membranes of N . crussu. From Thomas et al. (1991). Scale bars are 100 nm.
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Fig. 9). These may be resting on small lipid regions in the channel array. The protein-protein interactions in these domains may hold the sixchannel unit together.
C. freeze-fracturing and Shadowing
Freeze-fracture of outer membranes works well except when large arrays are generated by phospholipase treatment. Thus, only small VDAC arrays have been visualized by freeze-fracture (Lorie Thomas, unpublished observations). However, these are very revealing because they show an almost perfect hexagonal array of particles (the work of Lorie Thomas summarized in Colombini, 1994). Each particle (Fig. 8) is about the size of one six-channel unit. The deep grooves between the particles are likely to correspond to the openings of the channels as visualized in the freeze-dry images. Thus, despite their lower resolution, the freezefracture images indicate the same elevated region surrounded by the channel openings as being the functional unit. Indeed, the elevated region may be the site that binds soluble proteins such as the VDAC modulator and hexokinase.
FIGURE 8 Electron micrograph of an outer membrane from N . crmsn after freezefracture. (Courtesy of Lorie Thomas.)
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D. Freezing in Vitreous Ice The protein wall of VDAC’s pore was visualized by rapidly freezing the two-dimensional arrays in a thin layer of vitreous ice (Mannella ef al., 1989).These unstained specimens shquld be closest to the native structure. Like the results from negative staining, images from these frozen-hydrated specimens (Fig. 9) show that VDAC channels are essentially right cylinders perpendicular to the plane of the membrane. They indicate a cylinder diameter from the center of one protein wall to another of 3.8 nm. If the average length of amino acid side chains is 0.5 nm, this is consistent with a pore radius of 1.4 nm. The image in Fig. 9 also reveals the presence of “protein arms” (circled area) extending into the region surrounded by six VDAC channels. This region corresponds to the elevated regions seen after freeze-fracture and freeze-drying.
FIGURE 9 Correlation average of an electron micrograph of a VDAC array from N . crussu after rapid freezing in vitreous ice. From Mannella (1990). Fig. 3 . with permission from Birkhauser Verlag.
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E. Two Surfaces of the Crysfa1
The VDAC arrays analyzed by electron microscopy are usually located in closed vesicles derived from the mitochondria1 outer membrane. After phospholipase treatment, the vesicles shrink in size somewhat as some phospholipids are cleaved and removed by dialysis and the channel arrays grow in size. The vesicles flatten out on the electron microscope grid (Fig. 7) and even under the best conditions only half of them have channel arrays while the rest have only a random distribution of membrane proteins. Could it be that small preexisting seed crystals grow in two dimensions upon phospholipase treatment and these are only present in a portion of the mitochondria1 population? When these collapsed vesicles are visualized by transmission electron microscopy after negative staining, most often the vesicles that contain two-dimensional crystals have these crystals on both membranes (Mannella, 1982; Lorie Thomas, unpublished). The crystal lattices of these structures are mirror images of each other indicating that one crystal is upside down compared to the other (Thomas et ul., 1991).This is expected from a structure lacking a plane of symmetry. When these structures are viewed by the freeze-dry/shadow technique, where only the top crystal is visible, both types of crystals are seen (Fig. 7) indicating inside-out and right side-out vesicles (note that when negative stain reveals two superimposed crystals, one on the upper membrane and one on the lower membrane, the two crystal lattices are mirror images). The structure of both surfaces of the crystal looks very similar (Fig. 7). Both have a raised central area surrounded by six channels.
f. Structure of the O p e n and Closed States
It is generally assumed that the structures visualized by electron rnicroscopy represent the open state of VDAC. Successful attempts to close VDAC without electrical potentials by using chemical agents (Colombini ef ul., 1987) led to attempts to visualize the closed VDAC channels by electron microscopy. By using Konig’s polyanion, images of negatively stained arrays with a smaller pore opening were obtained (Mannella and Guo, 1990). The pore size was estimated to be 0.85 nm in radius. This is very similar to pore-size estimates based on the permeability of nonelectrolytes 10.9 nm, based on slight permeability to y-cyclodextrin (Colombini et ul., 1987)l.
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V. THE VOLTAGE-GATING PROCESS Voltage gating of membrane channels has two aspects: (1) the gating process-the structural change by which the protein goes from a state of high permeability to one of low permeability and (2) the voltage dependence-the process by which gating is coupled to changes in the membrane electrical potential. In the case of VDAC, the structural change is large. The pore radius has been estimated to decrease from about 1.2-1.5 nm to 0.8-0.9 nm. This is unlikely to be due simply to a local obstruction because the volume of the aqueous pore has been estimated to decrease by 20 to 40 nm3 based on water volume inaccessible to dextrans but accessible to sucrose (Zimmerberg and Parsegian, 1986). The channel’s selectivity is dramatically changed not only in magnitude but also in sign. The channel goes from weakly anion selective in the open state to weakly cation selective in the closed state (Colombini, 1980b; Zhang and Colombini, 1990; Benz and Brdiczka, 1992). This combination of steric and electrostatic changes indicates drastic changes in VDAC’s permeability to organic anions such as the metabolites that cross the outer membrane during mitochondria1 function (MgATP’-, MgADP-, succinate, phosphate, citrate, etc.). Portions of the VDAC channel that move upon channel closure were identified by the use of site-directed mutagenesis. Two independent lines of evidence point to the same region of the protein as being the part that moves upon voltage-dependent channel closure. Amino acid substitutions resulting in charge changes at particular locations on the VDAC channel could affect the selectivity of the open state and not the closed state (Peng el af., 1992a). Those particular sites must be close to the ionic flow in the open state but not in the closed state. Other sites had weaker than expected effects on the closed state selectivity indicating some displacement. Still others has comparable effects on both the open and closed state selectivities thus showing no evidence of displacement (shaded and boxed residues in Fig. 5). The sites that had no or weaker than expected effects on the closed state selectivity (but normal effect on the open state) were located primarily on the N-terminal and some on the C-terminal portions of the channel. These areas were proposed to move out of the channel upon channel closure. Since the net charge on these areas is positive, this motion would account not only for the reduction in pore size of the channel but also for the voltage dependence of the conformational change (due to the movement of charge through the electric field) and the change in selectivity because the remaining transmembrane strands would result in a net negative charge in the pore. Remarkably, most of the sites that seemed to move out of the channel based on selectivity measurements also influenced the voltage dependence
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of the channel (Thomas et al., 1993). An increase in positive charge at the sites increased the voltage dependence while a decrease in positive charge had the opposite effect. The changes in voltage dependence were discrete increases or decreases in the steepness of the voltage dependence as expected from an increase or decrease in the amount of charge moving through the membrane potential upon channel closure. Little change was observed in the conformational energy difference between the open and closed state indicating that the mutations were not simply favoring a particular structural state. One site (K248E) is indicated as moving out of the membrane by the selectivity measurements but had essentially no effect on the voltage dependence. However, since this site was close to the end of the transmembrane strand, it may move out of the pore without moving through a significant part of the membrane potential and thus charge change at this site would not affect overall voltage dependence. The lack of effect of mutations at positions 30 and 51 on the voltage dependence make it difficult to see what regions of the protein should be moving upon channel closure at both positive and negative potentials. While a clear overall picture is still elusive, the a-helix and the adjacent four p strands and the p strand at the C-terminus seem to be the parts that move in response to the electric field, although some of these may only move in response to a potential of one particular sign. A working model for voltage gating in VDAC (Fig. 10) involves the motion of a large portion of the protein through the membrane. This proposed model accounts for: (1) voltage dependence by proposing the movement of a charged domain through the membrane potential; (2) voltage gating at both positive and negative potentials; (3) the measured changes in channel diameter and volume; and (4) the change in ion selectiv-
Closed
-
Open
-
Closed
FIGURE 10 Model of the voltage gating of VDAC. The open channel is a barrel composed of one tilted a-helix and a cylindrical @-sheet wall. A membrane potential induces closure by driving part of the wall of the channel out toward the negative side of the membrane. Reopening involves the reincorporation of this domain into the channel.
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ity upon channel closure by moving a charged domain out of the membrane, An alternative proposal (Mannella, 1990) suggests that the a-helix might close the channel by entering the pore thus reducing its diameter and volume. While aesthetically pleasing, this notion does not account for: ( I ) voltage-dependent closure (the a-helix in yeast VDAC has no net charge and a dipole moment largely canceled out by the location of charged side chains): (2) selectivity changes associated with closure; and (3) the fact that charges at positions 15 and 19 on the helix influence channel selectivity in the open state and not at all or less than expected in the closed state.
VI. THE PROPERTIES OF VDAC CAN BE TUNED AND MODULATED Since VDAC’s properties have been studied largely in reconstituted systems, it is natural to wonder how different the properties are from the “physiological” state. This would include both changes in environment (lipids, ionic strength, etc.) and level of regulation or modulation. True in situ experiments examining VDAC’s electrophysiological properties have not been performed for obvious reasons. However, one can begin to gain a sense of the complexity of such changes in properties by considering the many ways VDAC has been found to be influenced and its properties markedly altered. The fact that VDAC reconstituted from widely different sources behaves almost the same way after reconstitution in planar membranes may yield the wrong impression that these properties are those found in the intact cell. Rather, the conserved behavior upon reconstitution may reflect the basic properties of the conserved structure of the channel. Yet, unlike many proteins, VDAC’s fundamental property of voltage dependence is affected very little by ionic strength and pH. Dramatic changes in voltage dependence occur only above pH 10 and below pH 4 (Bowen er al., 1985; Errnishkin and Mirzabekov, 1990). Indeed, steep voltage dependence can be easily observed in solutions as unphysiological as 80 mM CaCl, (Schein et al., 1976). However, this insensitivity to these environmental factors is simply the result of using the wrong factors. A. Osmotic Pressure
The voltage range at which VDAC switches between open and closed states can be shifted along the voltage axis by increasing the colloidal osmotic pressure of the medium (Zimmerberg and Parsegian, 1986). Thus
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the protein content of the cytoplasm and intermembrane space of the mitochondrion will tend to cause VDAC to close at lower voltages. These authors speculated that the cell could use this property to regulate the total protein content of the cytoplasm by restricting mitochondria1 ATP production through closure of VDAC in the outer membrane. Be that as it may, VDAC’s ability to close at low potentials is enhanced by the presence of proteins in the environment. 8. The VDAC Modulator
In addition to the nonspecific osmotic effect of proteins, mitochondria contain at least one protein that specifically changes VDAC’s properties (Holden and Colombini, 1988).This protein, dubbed the VDAC modulator, increases VDAC’s voltage dependence (Liu and Colombini, 1992b) and changes VDAC’s kinetic properties (Holden and Colombini, 1988).Closing rates are enhanced and opening rates are reduced (Fig. 11). The channels are only sensitive to the modulator when the modulator-containing side is made negative. If modulator is added to both sides then both gating processes are affected. At higher doses of modulator, VDAC channels tend to remain closed even in the absence of a membrane potential (Fig. 1 I ) . Positive potentials on the modulator-containing side are often capable of reopening such channels. The importance of this protein is indicated by its remarkable conservation. Modulator preparations from plants and fungi act on mammalian preparations of VDAC and vice versa (Liu and Colombini, 1991). This conserved recognition coupled with sensitivity estimated to be in the nanomolar range indicates the presence of a regulatory mechanism which tunes the protein to the state of the cell.
C. Ultrasteep Voltage Dependence VDAC’s voltage dependence is dramatically increased by the presence of soluble polyanions. Under “normal” reconstitution conditions, VDAC is steeply voltage dependent like that seen in the more widely studied channels in nerve and muscle. However, dextran sulfate (8 kDa) can increase VDAC’s voltage dependence 20-fold (Mangan and Colombini, 1987). The population of channels can switch from mostly open to mostly closed over a voltage range of less than 0.5 mV. This high voltage dependence is unique in all of biology. There is strong evidence that the polyanion partitions into the access resistance region of the channel in a
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._lr ‘0 0
Y
40[
Q
-
m c
1 min
n
’ The VDAC modulator induces an increase in the rate of voltage-dependent 0
-40
FIGURE 11
VDAC closure. Neirrospora cra.ssa VDAC channels were inserted into a membrane made from diphytanoyl phosphatidyl choline in which the channel closes at higher potentials. The addition of a VDAC modulator-containing protein extract is indicated. The upper trace shows the current recorded in response to the voltages applied (lower trace). Reprinted from Liu and Colombini (1991). Fig. I , with permission of the American Physiological Society.
voltage-dependent manner effectively amplifying the effect of the electric field. It probably interacts electrostatically with the positively charged voltage sensor resulting in channel closure. The production of this “ultrasteep” voltage dependence is not limited to dextran sulfate but has been observed with polyaspartic acid and even with highly negatively charged proteins and nucleic acids but at higher doses (Colombini et al., 1989). Perhaps the organized structure of the latter interferes with optimal interaction. A highly negatively charged polymer, referred to as Konig’s polyanion, which contains a mixture of carboxyl groups and nonpolar groups acts at much lower concentrations perhaps as a result of binding through the nonpolar residues (Colombini et al., 1987). The effect of the VDAC modulator may be partially through this process although it is not a highly negatively charged protein (pI=5).
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D. Donnan Potential The presence of charged macromolecules in the cytoplasm and the mitochondria1 intermembrane space must result in a Donnan potential across the outer mitochondrial membrane unless the colloidal charge in the two aqueous compartments happens to be exactly the same. The wellknown conversion between the condensed and orthodox versions of the mitochondria (Hackenbrock, 1968) changes the volume of the intermembrane space and therefore perhaps the protein concentration in this space. Such a change would be expected to change the Donnan potential across the outer membrane. Perhaps when mitochondria go from the rapidly respiring condensed state to the orthodox state they change the Donnan potential across the outer membrane and thus change the fraction of VDAC channels that are open. Naturally, the net charge on proteins can also be changed by such things as protein phosphorylation and pH changes. Indeed, Donnan potential changes must result in changes in the pH of one or both compartments and this can in turn change the net charge on protein. Thus possibilities exist for both positive and negative feedback.
E. Aluminum Inhibition Micromolar amounts of aluminum hydroxide strongly inhibit VDAC’s voltage dependence (Dill et af., 1987). While aluminum’s role in biology is unclear and is perhaps largely introduced as a result of industrialization, aluminum is a normal constituent found in human blood at micromolar levels. Thus, its presence may influence VDAC’s voltage dependence in uiuo. Unlike many other reported effects of aluminum, its action on VDAC is through a form found at physiological pH (Al(OH),) (Zhang and Colombini, 1989) and not through species more common at acid pH such as A13+. Al(OH)3 and other neutral metal trihydroxides act in a way that appears to be consistent with the neutralization of VDAC’ s voltage sensor but seems in fact to be some kind of indirect effect (Zhang and Colombini, 1990). The aluminum binding site does seem to translocate through the membrane in a way that is coupled to the channel gating process. F. NADH-lnduced Increase in Voltage Dependence
Micromolar quantities of NADH can double VDAC’s voltage dependence (Zizi et d.,1994). The oxidized form (NAD+) has no significant
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effects. These results indicate that the permeability of the outer membrane is sensitive to the glycolytc rate by sensing one of its most important products, NADH. This may be one of the molecular mechanisms behind the Crabtree effect. VII. FUNCTION The mitochondrion can be looked at as a debilitated organism now totally dependent on the host for survival. Yet the host is also dependent on the mitochondrion for many critical metabolic functions. Indeed there are no known eucaryotic cells that lack mitochondria or some endosymbiote. It seems reasonable that this symbiotic relationship must involve strict regulation, probably at various levels. VDAC channels are the primary pathway for the flow of metabolites across the mitochondrial outer membrane. Their highly conserved properties include a variety of regulatory mechanisms that could restrict the flow of metabolites between the cytoplasm and the mitochondrion. Such a bottle-neck could limit such things as energy production and mitochondrial growth and reproduction. Thus VDAC may play an important role in these and other processes. In addition to the host-symbiont relationship, the whole question of the regulation of energy metabolism in a cell may be influenced by the metabolic state of VDAC and VDAC’s interaction with other proteins. The Pasteur and Crabtree effects can be looked at as phenomena resulting from the interaction of two very different energy-producing systems in a cell (naturally the situation should be even more complex in chloroplastcontaining cells as well as in cells with more exotic energy-transducing mechanisms). The fact that the two different genes so far identified in humans that contribute VDAC differ in their ability to bind hexokinase indicates the importance of regulation (Blachly-Dyson et al., 1993). While the function of hexokinase binding to mitochondria via VDAC is controversial (Nelson and Kabir, 1985),this binding has been linked to adaptation to malignancy (Arora et af.,1992)and metabolic regulation (BeltrandelRio and Wilson, 1992). There is evidence that VDAC channels tend to be associated with sites of tight contact between the outer and inner membranes (Brdiczka ef al., 1989). The role(s) of these contact sites is unclear but may well be related to metabolic regulation or protein import. These contact areas may well subdivide the intermembrane space into different regions with different composition and properties. The role of VDAC channels reportedly located on the plasma membrane of cells (Blatz and Magleby, 1983; Nelson et al., 1984; Thinnes, 1992) is
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much more speculative. To dismiss the possibility that these large channels have any role because they are so conductive that they could kill the cell is to forget that sodium channels if left open for extended periods could kill cells. The key, naturally, is regulation, as it is for most cellular processes. These large channels seem to be kept closed until needed to perform some function. Situations that might require large channels are those in which high permeability is needed for short periods of time and those that require large molecules t o cross the membrane.
VIII. PROSPECTS The view of mitochondrial structure, function, and regulation that evolved in the 1960s and 1970s is too simple and does not account for more recent observations. The discovery of channels in the inner membrane and regulated channels in the outer membrane requires the development of theories and models of mitochondrial function that are more complex, imaginative, and daring. The ability of channels to respond to changes in environmental conditions and the levels of metabolic intermediates points to intricate regulation that may not be fully appreciated without the performance of difficult whole-cell experiments. Yet, much can still be learned by studying the properties and structures of the isolated components.
Acknowledgments I thank Dr. Martin Zizi for many stimulating discussions. This work was supported by ONR Grant N00014-90-J-1024.
References Arora, K. K . , Parry, D. M . , and Pedersen. P. L. (1992). Hexokinase receptors: Preferential enzyme binding in normal cells to non-mitochondria1 sites and in transformed cells to mitochondrial sites. J . Bioenerg. Biomembr. 24,47-53. BeltrandelRio, H.. and Wilson, J. E. (1992). Coordinated regulation of cerebral glycolytic and oxidative metabolism, mediated by mitochondrially bound hexokinase dependent on intramitochondrially generated ATP. Arch. Biochem. Biophys. 296, 667-677. Benz. R., and Brdiczka, D. (1992). The cation-selective substate of the mitochondrial outer membrane pore: Single-channel conductance and influence on intermembrane and peripheral kinases. J. Bioenerg. Biomembr. 24, 33-39. Blachly-Dyson, E.. Peng, S . Z.. Colombini, M., and Forte, M. (1989). Probing the structure of the mitochondrial channel, VDAC. by site-directed mutagenesis: A progress report. J. Bioenerg. Biomembr. 21, 471-483. Blachly-Dyson, E., Peng, S . Z., Colombini, M.. and Forte, M. (1990). Alteration of the selectivity of the VDAC ion channel by site-directed mutagenesis: Implications for the structure of a membrane ion channel. Science 247, 1233-1236. Blachly-Dyson. E.. Zambrowicz. E. B . , Yu. W. H., Adams. V.. McCabe. E. R. B., Adelman.
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J . , Colombini, M., and Forte, M. (1993). Cloning and functional expression in yeast of two human isoforms of the outer mitochondrial membrane channel, VDAC. J . Biol. Chem. 268, 1835-1841. Blatz, A. L.. and Magleby, K. L. (1983). Single voltage-dependent chloride-selective channels of large conductance in cultured rat muscle. Biophvs. J. 43, 237-241. Blumenthal. A,, Kahn. K., Beja, 0.. Galun. E.. Colombini. M.. and Breiman, A. (1993). Purification and characterization of the voltage-dependent anion-selective channel (VDAC) protein from wheat mitochondrial membranes. J. Plant Physiol. 101,579-587. Bowen. K. A..Tam. K.. andColombini. M. (1985).Evidence for titratablechargescontrolling the voltage dependence of the outer mitochondrial membrane channel, VDAC. 1. Membr. Biol. 86, 51-60. Brdiczka. D., Adams, V.. Kottke, M.. and Benz. R. (1989).Topology of peripheral kinases: Its importance in transmission of mitochondrial energy. I n “Anion Carriers of Mitochondrial Membranes” (A. Azzi. K. A. Nalqcz, M . J. Nalqcz, and L. Wojtczak, eds.). pp. 215-224. Springer-Verlag, New York. Bureau, M. H.. Khrestchatisky, M.. Heeren, M. A , . Zambrowicz, E. B., Kim. H.. Grisar, T. M., Colombini. M.. Tobin, A. J . , and Olsen. R. W. (1992). Isolation and cloning of a voltage-dependent anion channel-like M, 36.000 polypeptide from mammalian brain. J . Biol. Chem. 267, 8679-8684. Colombini. M. (1979). A candidate for the permeability pathway of the outer mitochondrial membrane. Nutrrre (London) 279, 643-645. Colombini, M. (1980a). The pore size and properties of channels from mitochondria isolated O ~ A J . Memhr. Biol. 53, 79-84. from N C I W O S ~crassa. Colombini, M. (1980b). Structure and mode of action of a voltage-dependent anion-selective channel (VDAC) located in the outer mitochondrial membrane. Ann. N . Y . Acad. Sci. 341,552-563. Colombini, M. (1986). Voltage gating in VDAC: Toward a molecular mechanism. I n “Ion Channel Reconstitution” (C. Miller, ed.), pp. 533-552. Plenum. New York. Colombini, M. (1989). Voltage gating in the mitochondrial channel, VDAC. J . Membr. Biol. 111, 103-1 1 1 . Colombini, M. (1994).The mitochondrial channel, VDAC. I n “Membrane Electrochemistry” (M. Blank and I. Vodyanoy, eds.), Vol. 235, Ch. 12. ACS Books, Washington, D.C. Colombini, M., Yeung, C. L., Tung. J., and Konig, T. (1987). The mitochondrial outer membrane channel, VDAC, is regulated by a synthetic polyanion. Biochim. Biophys. Acia 905, 279-286. Colombini, M., Mangan, P. S., and Holden, M. J. (1989). Modulation of the mitochondrial channel, VDAC, by a variety of agents. I n “Anion Carriers of Mitochondria1 Membranes” (A. Azzi, K. A. NalGcz, M. J. Nalqcz, and L. Wojtczak, eds.), pp. 215-224. Springer-Verlag. New York. Colombini, M., Peng, S. , Blachly-Dyson, E., and Forte, M. (1992). Probing the molecular structure and structural changes of a voltage-gated channel. I n “Methods in Enzymology” (B. Rudy and L. Iversen, eds.), vol. 207, pp. 432-444. Academic Press, London. De Pinto, V., and Palmieri, F. (1992). Transmembrane arrangement of mitochondria1 porin or voltage-dependent anion channel (VDAC). J . Bioenerg. Biomemhr. 24, 21-26. Dill, E. T., Holden, M. J., and Colombini, M. (1987). Voltage gating in VDAC is markedly inhibited by micromolar quantities of aluminum. J . Membr. Biol. 99, 187-196. Ermishkin, L. N., and Mirzabekov, T. A. (1990). Redistribution of the electric field within the pore contributes to the voltage dependence of mitochondrial porin channel. Biochim. B i ~ p h y sActa . 10219 161-168. Finkelstein, A., and Anderson, 0. S. (1981). The gramicidin A channel: A review of its
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permeability characteristics with special reference to the single-file aspect of transport. J . Membr. Biol. 59, 155-171. Forte. M.. Guy, H. R., and Mannella. C. A. (1987). Molecular genetics of the VDAC ion channel: Structural model and sequence analysis. J . Bioenerg. Biomembr. 19,341-350. Hackenbrock. C. R. (1968). Ultrastructural basis for metabolically-linked mechanical activity of mitochondria. 11. Electron-transport linked ultrastructural transformations in mitochondria. J . Cell B i d . 37, 345-357. Holden. M. J.. and Colombini. M. (1988). The mitochondrial outer membrane channel. VDAC. is modulated by a soluble protein. FEES Lett. 241, 105-109. Holz. R.. and Finkelstein. A . (1970). The water and non-electrolyte permeability induced in thin lipid membranes by the poloyene antibiotics nystatin and amphotericin B. J . G P I IPliysiol. . 56, 125-135. Kasumov. Kh.M.. Borisova. M. P.. and Vainshtein. V. A. (1979). How do ionic channel properties depend on the structure of polyene antibiotic molecules. Biochim. Biophys. Acta 551, 229-237. Kayser. H.. Dratzin. H. D.. Thinnes, F. P.. Gotz, H.. Schmidt. W. E.. Eckart, K., and Hilschmann. N. (1989). Characterization and primary structure of a 31-kD porin from human B lymphocytes (Porin 31HL). Biol. Chem. Hoppe-Seyler 370, 1265-1278. Kleene. R.. Pfanner. N.. Pfaller, R . . Link. T. A., Sebald, W.. Neupert, W., and Tropschug, M. (1987).Mitochondrial porin of Neurosportr crussu: cDNA cloning, in uifro expression and import into mitochondria. EMBO J . 6, 2627-2633. Linden. M., and Gellerfors, P. (1983). Hydrodynamic properties of porin isolated from outer membrane of rat liver mitochondria. Biochim. Biophys. Acta 736, 125-129. Liu. M.. and Colombini. M. (1991). Voltage gating in the mitochondrial outer membrane channel. VDAC. is regulated by a very conserved protein. A m . J . Physiol. 260, C371-C374. Liu, M.. and Colombini, M. (1992a). Regulation of mitochondrial respiration by controlling the permeability of the outer membrane through the mitochondrial channel, VDAC. Biochim. Biophys. Acta 1098, 255-260. Liu. M. Y.,and Colombini, M. (1992b). A soluble protein increases the voltage dependence of the mitochondrial channel. VDAC. J . Bioenerg. Biomembr. 24,41-46. Mangan, P. S . , and Colombini, M. (1987). Ultra-steep voltage dependence in a membrane channel. Proc. Natl. Acad. Sci. U S A . 84, 4896-4900. Mannella, C. A. (1982). Structure of the outer mitochondrial membrane: Ordered arrays of pore-like subunits in outer-membrane fractions from Neurospora crassa mitochondria. J . Cell B i d . 94, 680-687. Mannella. C. A. (1986). Mitochondrial outer membrane channel (VDAC.porin1: Twodimensional crystals from Nertrosporcr. In "Methods in Enzymology" (S. Fleischer and B. Fleischer. eds.). Vol. 125. pp. 595-610. Academic Press, Orlando. FL. Mannella, C. A. (1987). Electron microscopy and image analysis of the mitochondrial outer membrane channel, VDAC. J . Bioenerg. Biomembr. 19, 329-340. Mannella, C. A . (1990). Structural analysis of mitochondrial pores. Experientia 46, 137-145. Mannella, C. A.. and Guo, X.-W. (1990). Interaction between the VDAC channel and a polyanionic effector. Biophys. J . 57, 23-31. Mannella. C. A., Colombini. M., and Frank, J. (1983). Structural and functional evidence for multiple channel complexes in the outer membrane of Neurospora crassa mitochondria. Proc. Natl. Acad. Sci. U.S.A. 80, 2243-2247. Mannella. C. A., Guo, X.-W., and Cognon. C. (1989). Diameter of the mitochondrial outer membrane channel: Evidence from electron microscopy of frozen-hydrated membrane crystals. FEBS Leu. 253, 231-234.
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Mannella, C. A., Forte, M.. and Colombini. M . (1992). Toward the molecular structure of the mitochondrial channel, VDAC. J . Bioenerg. Biomembr. 24, 7-19. Mihara, K., and Sato, R . (1985). Molecular cloningand sequencing of cDNA for yeast porin. an outer mitochondrial membrane protein: A search for targeting signal in the primary structure. EMBO J . 4, 769-774. Nelson, B. D.. and Kabir, F. (1985). Adenylate kinase is the source of ATP for tumor mitochondrial hexokinase. Biochim. Biophys. Acta 841, 195-200. Nelson, D. J., Tang, J . M.. and Palmer, L. G. (1984). Single-channel recording of apical membrane chloride conductance in A6 epithelial cells. J . Membr. Biol. 80, 81-89. Parsons, D. F., Bonner, W. D.. Jr., and Verboon. J. G . (1965). Electron microscopy of isolated plant mitochondria and plastids using both thin-section and negative staining techniques. Can. J . Bot. 43, 647-655. Peng, S.. Blachly-Dyson, E., Forte, M.. and Colombini. M. (1992a). Large scale rearrangement of protein domains is associated with voltage gating of the VDAC channel. Biophys. J . 62, 123-135. Peng, S.. Blachly-Dyson, E., Forte, M.. and Colombini, M. (1992b). Determination of the number of polypeptide subunits in a functional VDAC channel from Saccharomvces cerevisiae. J . Bioenerg. Biomembr. 24, 27-3 1 . Roos. N., Benz, R . , and Brdiczka, D. (1982). Identification and characterization of the poreforming protein in the outer membrane of rat liver mitochondria. Biochim. Biophys. Acra 686,204-214. Schein. S. J.. Colombini. M.. and Finkelstein, A. (1976). Reconstitution in planar lipid bilayers of a voltage-dependent anion-selective channel obtained from Paramecium mitochondria. J . Membr. B i d . 30, 99-120. Scherrer. R., and Gerhardt, P. (1971). Molecular sieving by the Bacillus megarerium cell wall and protoplast. J . Bacteriol. 107, 718-735. Thinnes, F. P. (1992). Evidence for extra-mitochondria1 localization of the VDAClporin channel in eucaryotic cells. J . Bioenerg. Biomembr. 24, 71-75. Thomas, L.. Kocsis, E., Colombini, M., Erbe, E., Trus, B. L., and Steven. A. C. (1991). Surface topography and molecular stoichiometry of the mitochondrial channel, VDAC, in crystalline arrays. J. Struct. Biol. 106, 161-171. Thomas, L., Blachly-Dyson, E., Colombini, M., and Forte, M. (1994). Mapping of residues forming the voltage sensor of the VDAC ion channel. Proc. Natl. Acad. Sci. U.S.A. 90,5446-5449. Vodyanoy, I . , Bezrukov, S. M., and Colombini, M. (1992). Measurement of ion channel access resistance. Biophys. J . 61, Al14. Weiss, M. S., Kreusch, A., Schiltz, E., Nestel, U., Welte. W., Weckesser, J . , and Schulz, G . E. (1991). The structure of porin from Rhodobacter capsulatus at 1.8 A resolution. FEBS Lett. 280, 379-382. Werkheiser, W. C . , and Bartley, W. (1957). The study of steady-state concentrations of internal solutes of mitochondria by rapid centrifugal transfer to a fixation medium. Biochem. J . 66, 79-91. Wojtczak, L., and Zaluska, H. (1969). On the permeability of the outer mitochondrial membrane to cytochrome c. I. Studies on whole mitochondria. Biochim. Biophys. Acta 193, 64-72. Zalman, L. S . , Nikaido, H., and Kagawa, Y.(1980). Mitochondria1 outer membrane contains a protein producing nonspecific diffusion channels. J . Biol. Chem. 255, 1771-1774. Zarnbrowicz, E. B., and Colombini, M. (1993). Zero-current potentials in a large membrane channel: A simple theory accounts for complex behavior. Biophys. J . 65, 1093-1 100.
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Zhang. D . W . . and Colombini. M . (1989). Inhibition by aluminum hydroxide of the voltagedependent closure of the mitochondrial channel. VDAC. Biochim. Bioph.vs. A c f a 991, 68-78. Zhang. D . - W . . and Colombini, M . (1990). Group IIIA-metal hydroxides indirectly neutralize the voltage sensor of the voltage-dependent mitochondrial channel. VDAC. by interacting with a dynamic binding site. Biochim. Biophys. A d a 1025, 127-134. Zimmerberg. J.. and Parsegian. V. A. (1986). Polymer inaccessible volume changes during opening and closing of a voltage-dependent ionic channel. Nature (London)323,36-39. Zizi. M . . Forte. M . . Blachly-Dyson. E.. and Colombini. M. (1994). NADH regulates the gating of VDAC. the mitochondrial outer membrane channel. J . B i d . Chem. 269, 1614-16 16.
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CHAPTER 5
Regulation of Chloride Channels in Lymphocytes Michael D. Cahalan and Richard S. Lewis* Department of Physiology and Biophysics. University of California at Irvine. Irvine. California 92717: and *Department of Molecular and Cellular Physiology. Stanford University. Stanford, California 94305
I. Functions of T and B Lymphocytes II. Ion Channel Phenotype of Lymphocytes A. Voltage-Gated K' {K(V)}Channels
B. Calcium-Activated K' {K(Ca)}Channels C. Mitogen-Regulated Ca?+ Channels 111. Patch-Clamp Studies of Lymphocyte CI- Channels A. Volume-Regulated Mini-CI- Channel B. Kinase-Regulated Midi-CI- Channel C. Maxi-C1- Channels IV. Functional Roles of CI- Channels A. Contribution of Pcrto Resting Potential B. Mitogenesis C. Volume Regulation V. Summary and Prospects References
1. FUNCTIONS OF T A N D B LYMPHOCYTES
Lymphocytes provide protection against the onslaught of innumerable pathogens. The molecular and cellular bases of immunity reside within three conceptually separate but interlocking cellular responses. The recognition of antigens by specific receptors sets off an intracellular cascade of signal transduction, which in turn leads to a variety of effector functions. Antigen specificity is provided during primary differentiation from bone Current Topics in Membranes. Volume 42 Copyright 0 1994 by Academic Press, Inc. All rights of reproduction in any form reserved.
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marrow stem cells, giving rise through the somatic rearrangement of Tand B-cell antigen receptor genes to specific membrane receptors. The Tcell receptor for a given T cell then is able to recognize a single, specific antigen bound to a major histocompatibility (MHC) protein at the surface of an antigen-presenting cell. The B-cell antigen receptor, or membrane immunoglobulin, recognizes its corresponding antigen without the need for antigen presentation. Ligand binding brings receptors laterally into proximity with other receptors in the membrane and results in the activation of kinases, phosphatases, and phospholipase C. The resulting effector functions depend upon transcriptional activation of additional sets of genes which vary according to the specific lymphocyte subset. In general, these later responses include secretion of lymphokines, cell proliferation, and further differentiation into memory cells or antibody-secreting plasma cells, for example. For the immune response to work, lymphocytes must be able to disperse throughout the body, borne in part by the flow of blood and lymph and also by adhering to and moving along tissue surfaces. They must also be able to regulate their volume and survive up to decades. Watching the interaction of T and antigen-presenting cells at the microscopic level. we can visualize the immunosurveillance without which we would succumb to infection and tumors. These remarkable cells, each unique in having undergone differentiation by genetic recombination to yield a specific receptor that can recognize a single, foreign antigen, are also endowed with an array of ion channels that helps them to perform essential cellular functions. The purpose of this review is to focus on chloride channels in T and B lymphocytes. We discuss their distribution, regulation, biophysical properties, and similarities with channels in other cell types, as determined primarily by patchclamp experiments, and discuss their possible role in lymphocyte functions. Before describing properties of the chloride channel subset, we present a brief overview of the other types of channels found (and not found) in lymphocytes. II. ION CHANNEL PHENOTYPE OF LYMPHOCYTES
Patch-clamp techniques have revealed a diverse set of ion channels in lymphoid cells, including several distinct types of potassium, calcium, and chloride channels (reviewed by Lewis and Cahalan, 1990; Premack and Gardner, 1991; Cahalan et al., 1992). Biochemical assays of lymphocyte function following mitogen stimulation have illuminated some of the essential roles that these channels play in the activation and effector functions of T and B lymphocytes. It has become clear that ion channels
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mediate a variety of cellular behaviors, including the Ca’+ signal during antigen activation of lymphocytes, the secretion of lymphokines, killing of target cells, progression through the cell cycle, and volume regulation in response to osmotic stress. Ion channels in cells of the immune system offer promising targets for therapeutic agents in the treatment of a variety of disorders, including immunodeficiency, autoimmunity, leukemias and lymphomas, graft rejection, and inflammation. A. Voltage-Gated K + {K(V)} Channels Except for occasional sightings in lymphoid cell lines, voltage-gated Na’ and Ca” channels have not been observed; thus lymphocytes and related cell lines are generally not electrically excitable. Nevertheless, the most commonly seen and dominant channel under resting conditions is a voltage-activated K + channel. Originally described in quiescent human T lymphocytes (DeCoursey et al., 1984; Matteson and Deutsch. 1984), the “type n” channel has been the subject of intensive investigation, in part because agents which block the type n channel also inhibit mitogenregulated cell proliferation in both T and B cells (DeCoursey et d,, 1984; Chandy er al., 1984; Deutsch et a/., 1986; Amigorena et ul., 1990). A Shuker-related gene (Kvl.3) encoding the type n channel has been cloned, sequenced, and expressed in Xenopus oocytes, as well as in mammalian cell lines (Grissmer et al., 1990a). Two additional voltage-gated K’ channels have been described in murine thymocytes and T cells: the n‘ channel, with properties only slightly different from those of type n, and the type l channel, with expression restricted normally to CD8’ cells (DeCoursey rt al., 1987a; Lewis and Cahalan, 1988). The type 1 channel is abnormally expressed in CD4- CD8- T cells with autoimmune pathologies, including murine models of lupus erythematosus, arthritis, diabetes, and multiple sclerosis (Chandy et al., 1986,1990; Grissmer et al., 1988,1990b). The gene (Kv3. I ) encoding the type /channel has also been identified (Grissmer et ul., 1992a).The type n channel is normally the predominant conductance in quiescent human T lymphocytes and is responsible for establishing the resting membrane potential of -50 to -70 mV, near the foot of the conductance-voltage relation, where only a small fraction of the available 500 or so channels per cell are open (Cahalan et al., 1985). B. Calcium-Activated K + { K(Ca)} Channels
In addition to the three voltage-gated K’ {K(V)} channels, at least two types of Ca*+-activated K t {K(Ca)} channels have been described in T
Michael D. Calahan and Richard S . Lewis
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and B cells (Mahaut-Smith and Schlichter, 1989; Mahaut-Smith and Mason, 1991). A low-conductance channel, especially prevalent in Jurkat T cells, is selectively blocked by aparnin, a toxin from bee venom, at subnanomolar concentrations (Grissmer et a / ., 1992b). A second, higher conductance channel is blocked by charybdotoxin (CTX). a scorpion venom, at nanomolar levels (Grissrner et al., 1993). The latter channel is found in normal human T and B cells and becomes abundant in proliferating cells following mitogenic activation (Grissmer et al. , 1993; Partiseti et a/., 1992,1993).Both of these channels are opened by a rise in cytosolic Ca”, with steep Cazt dependence (Hill coefficient of 4, midpoint -400 nM) at levels seen following mitogen stimulation. The Ca’+-activated K t channels serve to hyperpolarize the membrane potential during the mitogen-stimulated rise in cytosolic [Ca’+]. C. Mitogen-Regulated Caz Channels +
Shortly after rnitogen stimulation, cytosolic [Ca?+]rises from its resting level of about 100 nM and often begins to oscillate (Lewis and Cahalan, 19891, reaching levels > 1 p M at the peak of each oscillation. This “Ca” signal” is believed to be one of several early triggering signals in the activation of T lymphocytes by mitogens. The measured influx of Ca2+ ions during this time translates to an estimated whole-cell current carried by Ca2+ions on the order of 1 PA. Two candidates have been proposed to underlie the Ca2’ influx: a 7-pS, Ca2+ permeable channel activated directly by IP, (Kuno and Gardner, 1987) and a very low-conductance (10 fs), Ca2+-selectivechannel activated indirectly by depletion of intracellular Ca2+stores (Lewis and Cahalan, 1989). The Ca*+-selectivechannel is likely identical to a conductance found in mast cells, termed Icrac for “calcium-release-activated conductance” (Hoth and Penner, 1992). Investigations in Jurkat T cells have demonstrated that this lowconductance Ca2+-selectivepathway is the major influx mechanism activated (McDonald et a / . , 1993; Zweifach and Lewis, 1993). We have analyzed the contributions of Ca2+ and K + channels to mitogen-stimulated Ca2+signaling in Jurkat T cells (Lewis and Cahalan, 1989;Grissmer et al., 1992b).Activation of voltage-dependent Ca*+-selective channels provides the Ca2+ influx which generates the rising phase of the [Ca2+Iisignal. The amount of Ca2+released from intracellular stores is limited; the Ca2+ signal depends primarily upon influx driven by a negative membrane potential. At elevated [Ca2+Ii,the Ca2+channels are inhibited, providing negative feedback to help terminate an oscillation. Potassium channels provide the electrical driving force for Ca2+entry by
5 . Chloride Channel Regulation in Lymphocytes
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maintaining the membrane potential. In Jurkat cells, [Ca" Ii oscillations are abolished by simultaneous addition of apamin and CTX to block both calcium-activated K(Ca) and voltage-gated K( V ) channels (Grissmer er al., 1992b). The relative contributions of K(V) and K(Ca) channels may vary in different T-cell subsets, since their levels of expression can change dramatically depending upon the state of activation. In principle, activity of other channels that influence the membrane potential could play an indirect role in modulating the Ca2+signal. The possible involvement of Cl- channels in lymphocyte activation and volume regulation is reviewed at the conclusion of this chapter. Table I summarizes the major types and properties of ion channels described to date. TABLE I Lymphocyte Ion Channels Channel
Gating (midpoint)
Pharmacology (Ki value)
Size(pS)
K(V) Type n (Kv1.3)
CTX -35 mV
18
Type n' -35 mV
18
TEA (10 m M ) TEA (I00 m M )
(3 n M ) CTX (3 nM)
Type 1 (Kv3.1)
- 5 mV
27
TEA (0.1 m M )
K(Ca) Mini 400 nM
Midi Caz+ IP3-gated "Icrac" CI Mini Midi Maxi
300 nM
IP3 Ca2+ stores depletion Volume Kinase Depolarization Patch excision Voltage
5" 350
TEA (2 mM) TEA (40 m M )
Apamin ( < I nM) CTX (3 nM)
I 0.01
2-3"
Ni2+ ( 1 mM) NPPB
DIDS (17 pM$'
(50 p M )
SITS~
zn?+
40-50" 400 pS" Many sublevels
( 5 mM)
Determined under conditions of symmetrical permeant ion concentration. mV for external DIDS and SITS block of the mini-CI- channel (Lewis et a / . . 1993). and at 0 mV for internal SITS block of the maxi-CI- channel (Bosma, 1989). "
' Block is voltage dependent. K, was evaluated at f40
Michael D. Calahan and Richard S. Lewis
108 111. PATCH-CLAMP STUDIES
OF LYMPHOCYTE CI- CHANNELS
A. Volume-Regulated Mini-CI- Channel
Cells of the lymphocytic lineage (T and B lymphocytes and related cell lines) express a class of volume-activated, low-conductance C1- channels that we refer to as mini-Cl- channels. Such channels have been characterized in murine thymocytes and splenic T cells, human peripheral blood T cells, and the human leukemic Jurkat T-cell line (Cahalan and Lewis, 1988; Lewis r f al., 1993). Mini-C1- channels outnumber other types of channels in lymphocytes. Based on an estimate of unitary conductance, lymphocytes express lo4mini-CI- channels per cell. Despite their abundance, the channels are inactive in resting cells and only contribute significantly to membrane conductance if the cells are swollen, e.g., during exposure to hyposmotic solutions, These and other properties suggest a role as the swelling sensor for the regulatory volume decrease (RVD) response. The properties and activation mechanism of the mini-CI- channel are summarized below.
-
1. Regulation Mini-C1- channels in lymphocytes are controlled by the transmembrane osmotic gradient. Conditions leading to cell swelling, such as exposure to hyposmotic extracellular or hyperosmotic intracellular solutions, promote channel activation (Cahalan and Lewis, 1988; Lewis et al., 1993). The chloride conductance, g,,, can reach values of several nanosiemens, making a major contribution to the overall membrane conductance at voltages near the resting potential. The relationship between cell volume and CIchannel activation has been studied quantitatively using whole-cell recording and videomicroscopy (Ross et al., 1994).In Jurkat T cells exposed to a 100-mOsm stimulus, Cl- channel activation began -60 sec following the onset of swelling. During this period, the cell volume increased by an average of 19%. This corresponds well with the apparent threshold for activation of C1- flux by hyposmotic solutions (Sarkadi er al., 1984b). The activation mechanism for the mini-CI- channel is not yet completely understood. Channel gating is not detectably voltage dependent in the range -100 to + 100 mV, as steps to these potentials elicit a constant current with no sign of time-dependent activation or inactivation (Lewis et al., 1993). Suction applied to the pipette’s interior reversibly opposes channel opening by an osmotic stimulus, suggesting that membrane stretch is part of the activation mechanism. However, the amount of suction
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required is much smaller than the equivalent osmotic pressure provided by the 100-mOsm gradient (Lewis et al., 1993). Intracellular second messengers such as Ca?+or cAMP are not sufficient to activate the channels, as neither ionomycin nor inclusion of cAMP in the recording pipette has an effect. Intracellular EGTA (10 m M ) does not alter g,, induction, indicating that a Ca2+rise is not necessary for channel activation. However, these results do not rule out a possible modulatory role for intracellular Ca’+. One important clue to the activation mechanism is that channel opening requires a source of intracellular ATP. During whole-cell recordings with ATP-free pipette solutions, the inducibility of gcl declines over several minutes. In contrast, responsiveness to an osmotic gradient is preserved for > I 0 min by including 4 mM ATP in the pipette, or by using the less-invasive perforated-patch recording technique (Lewis et d., 1993). The mechanism by which ATP exerts its effect is not known, but the possibilities include roles as an energy or phosphate donor or an allosteric effector. A poorly hydrolyzable analogue, ATPyS, can also support the activation of C1- channels during osmotic swelling (Cahalan and Lewis, 1988). Insertion of “new” CI- channels from an intracellular vesicular pool is one mechanism for the slow modulation of Cl- conductance during the cell cycle in developing ascidian embryos (Block and Moody, 1990). Should such a mechanism underlie gcl activation in T cells, an increase in membrane area and hence membrane capacitance (C,)would accompany the increase in C1- current. However, C , actually decreases slightly during the induction of gcl, indicating that C1- channels preexist in the plasma membrane (Ross et al., 1994). Based on a comparison between measured values of C, and theoretical values predicted from cell diameter and specific membrane capacitance, 40-70% of the surface membrane area of Jurkat T cells may be from ruffles and/or microvilli. Swellinginduced activation of gClmay therefore involve the resorption of these structures, leading to the opening of C1- channels already present in the plasma membrane. A decrease in the number of microvilli in hypotonically treated T cells has been observed using scanning electron microscopy (Cheung et al., 1982; Grinstein et al., 1984).
2. Biophysical Properties and Pharmacology Mini-C1- channels are -20-fold more permeable to C1- than Naf or K’. The channel selects anions, with the permeability sequence I (1.35) > SCN (1.23) > NO,, Br (1.17) > CI- (1.0) > MeSO, (0.43) > acetate (0.32), propionate (0.27) > ascorbate (0.19) > aspartate (0.11) and gluconate (0.lo), with the permeability of each ion relative to CI- in parentheses
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Michael D. Calahan and Richard S . Lewis
(Lewis et al., 1993). In symmetrical C1--containing solutions, the current-voltage relation shows modest outward rectification (fcl, + SOmV/fCI, -50 mV-l.4). The size and kinetic behavior of mini-CI- channels in lymphocytes has been estimated using fluctuation analysis of whole-cell CI- current (Lewis et ul., 1993). The estimated ratio of variance to mean current during the slow induction of gcl is -0.2 pA at a membrane potential of -80 mV, corresponding to achord conductance of -2-3 pS. The Cl- noise spectrum under conditions of low open probability is approximated by a Lorentzian function with a cutoff frequency of 386 Hz. These results predict a mean open time of -0.4 msec. Osmotically activated Cl- current has not yet been detected at the single-channel level in membrane patches. Mini-CI- channels are blocked in a voltage- and time-dependent manner by the stilbene disulfonates DIDS and SITS (Lewis et al., 1993). Blockade increases with depolarization, showing an e-fold increase every 19-22 mV and K ivalues of 17 p M (DIDS) or 89 p M (SITS) at +40 mV, the voltage at which blockade is maximal. The voltage dependence makes the blocking action of moderate doses (100-500 p M ) of DIDS or SITS undetectable at voltages near the resting potential of these cells, a factor to take into account when using these agents to probe channel function in intact cells. The time dependence of channel blockade is biexponential, suggesting that the drugs may bind to multiple sites within the membrane electric field (Lewis et al., 1993). Mini-C1- channels are also blocked by NPPB, CPZ, and niflumic acid, with K , values near 50 p M (G. Ehring and M. D. Cahalan, unpublished observations). The mini-CI- channel is insensitive to verapamil or 1,9-dideoxyforskolin (Lewis et ul., 1993),agents reported to block the P-glycoprotein-associatedC1- current (Valverde ef al., 1992).
3. Comparison with C1- Channels in Lymphocytes and Other Cells The osmotically sensitive mini-Cl- channel of lymphocytes is distinct from other C1- channels present in lymphocytes, but shares important biophysical characteristics with selected C1- channels of several other cell types, including cells of both neuroectodermal and hematopoietic lineages. Mini-CI- channels in chromaffin cells, lymphocytes, mast cells, and neutrophils are regulated differently, as described below, raising the possibility that the mini-C1- channel of lymphocytes is a member of a larger group of low-conductance CI- channels whose regulation is linked to cell-type-specific functions. Mini-CI- channels are distinct from CAMP-activated CI- channels in T cells. Like the mini-CI- conductance, the whole-cell C1- conductance activated by CAMP or PGE, in Jurkat T cells lacks voltage dependence and displays a mild degree of outward rectification (Maldonado et al.,
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1991). However, the two differ in that the cAMP/PGE,-activated current is not consistently blocked by 100 pM DIDS. and CAMPhas no detectable effect on mini-CI- channels. Furthermore, single CAMP-activated CIchannels in T cells have a much larger unitary conductance (-40 pS at 0 m V ) than the mini-CI- channels. Mini-CI- channels do not appear to underlie other volume-activated CI- currents reported in transformed normal and cystic fibrosis (CF) B cells (McDonald et al., 1992); possibly lymphocytes possess multiple volume-activated CI- pathways. McDonald et al. (1992) reported a hypotonically activated CI- current that inactivates at potentials greater than + 50 mV. The current appears similar in its regulation and kinetic properties to volume-sensitive C1- conductances described in greater detail in the human colonic cell line T84 (Worrell et a/., 1989; Solc and Wine, 1991). in human airway epithelial cells ( J . D. McCann et N / . , 19891, and in a human intestinal epithelial cell line (Kubo and Okada. 1992). The epithelial CI- currents are similar to mini-CI- channels in their dependence on osmolarity and selectivity for anions over cations (P,,/P,,-20; Worrell et a/., 1989). They also show a similar outward rectification ( I , , , mV/f-.cO ,,,” = 1.5 to 2) and similar, but not identical, selectivity among anions (Kubo and Okada. 1992). However, these epithelial C1- currents display pronounced inactivation at potentials > +40 mV and, at least in T84 cells, a significantly larger single-channel conductance (50-75 pS; Worrell et al., 1989; Solc and Wine, 1991). Thus, this class of volume-activated C1channels differs in both gating and conductance properties from the miniCI- channel. Mini-CI- channels have been found in neutrophils, another cell of the hematopoietic lineage (Stoddard et al., 1993). As are their counterparts in T cells, the neutrophil channels are activated by hyperosmotic internal or hyposmotic external solutions, a process which is opposed by suction through the pipette; are not voltage- or Ca2 -dependent; have a unitary conductance of 1.5 pS by variance analysis; show a similar, though not identical, anion selectivity; and are blocked in a voltage-dependent manner by SITS. These channels may be involved in the RVD response of neutrophils (Stoddard er al., 1993), in a manner analogous to the proposed function of mini-C1- channels in T cells (Cahalan and Lewis, 1988; Lewis et ul., 1993). Nonhematopoietic cells also express mini-CI- channels, although with additional modes of regulation. In adrenal chromaffin cells, whole-cell CIcurrent can be activated by a positive transmembrane osmotic gradient (Doroshenko and Neher, 1992) or by intracellular GTPyS (Doroshenko el al., 1991). Like the T cell’s mini-Cl- channel, these currents lack voltagedependent gating, have a low permeability to aspartate (P,,,IPcl-O. l ) , +
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show modest outward rectification, are blocked reversibly by DIDS in a voltage-dependent manner, and have a unitary conductance of 1-2 pS as estimated from noise analysis. With ATP-free internal solutions, a sustained osmotic gradient induced a transient I,, in chromaffin cells (Doroshenko and Neher, 1992), much like the transient behavior of the osmotically activated CI- current in lymphocytes under ATPi-free conditions (Lewis et a / . , 1993). However, the Cl- current in chromaffin cells does not show the same dependence on pipette pressure: a brief pressure pulse elicits the same increase in gClas a sustained osmotic stimulus, and negative pressure of up to -55 cm H 2 0 (-5.4 kPa) does not inhibit gcl (Doroshenko and Neher, 1992). These results suggest that, in chromaffin cells, additional steps may intervene between cell membrane distention and channel activation, such that termination of swelling does not immediately curtail channel activation. Interestingly, inhibitors of phospholipase A2 and lipoxygenase prevent the induction of g,, by GTPyS in chromaffin cells. Thus, activation of CI- channels in these cells may involve a second messenger generated by arachidonic acid metabolism (Doroshenko, I99 1 ; Doroshenko and Neher, 1992). The possible involvement of this pathway in activation of mini-CI- channels in lymphocytes has not been explored. A small-conductance C1- channel described in mast cells is also similar in many respects to the lymphocyte mini-Cl- channel, excluding its mode of regulation. The mast cell CI- channel is activated by cell-surface receptors (substance P, compound 48/80) as well as by intracellular application of CAMP, high Ca2+,GTPyS, and possibly other mediators invoked by cell-surface receptors. The induction of g,, by intracellular second messengers is slow, particularly in the case of Ca2+,indicating that they are unlikely to activate the channel directly (Penner et a!., 1988; Matthews et al., 1989). In these cells, swelling is not tightly correlated with the induction of the current, and direct manipulation of cell volume by positive or negative pressure on the pipette causes only small and slow changes in Icl (Matthews et al., 1989). Despite these obvious differences in its regulation, the mast cell C1- channel shares permeation and pharmacological properties with mini-CI- channels in lymphocytes, including a unitary conductance of 1-2 pS and a sensitivity to blockade by DIDS. Osmotically activated C1- currents recorded in fibroblasts and cardiac cells also resemble the mini-CI- channel currents of T cells, although they have not been characterized in great detail. In human dermal fibroblasts, hyposmotic extracellular or hyperosmotic intracellular solutions induce a C1- conductance with moderate outward rectification and voltageindependent gating (Estacion, 1991). Intracellular ATP enhances the induction rate, duration, and amplitude of g,,, as in lymphocytes. In cardiac myocytes, a transmembrane hyposmotic gradient activates a Cl- conduc-
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tance that is voltage independent, shows moderate outward rectification, and has a permeability sequence of NO, > CI- > MeSO, > aspartate (Tseng, 1992). Neither the cardiac nor the fibroblast CI- current has been analyzed at the microscopic level, but these results provide additional evidence that the prevalence of volume-activated mini-CI- extends beyond the borders of the hematopoietic lineage. What gene or genes encode volume-regulated mini-C1- channels? Jentsch and colleagues have shown that the CIC-2 gene induces a volumeregulated C1- conductance in Xenopirs oocytes (Thiemann et al., 1992; Grunder et al., 1992). Like the lymphocyte mini-CI- channel, the CIC-2 gene product is opened by cell swelling and lacks voltage-dependent gating, but the open channels rectify inwardly and have a different sequence of permeant ions than the outwardly rectifying mini-CI- channel. Furthermore, strong hyperpolarization activates CIC-2 channels. It is not known whether lymphoid cells express mRNA for CIC-2. although the expression of this gene is widespread. In other cell types, another candidate gene is MDRl which codes for P-glycoprotein. an active transporter responsible for the resistance of cancer cells to chemotherapeutic agents. Valverde and colleagues (1992) reported that fibroblasts transfected with the MDRl gene expressed a volume-regulated CI - channel, with many properties similar to the lymphocyte mini-CI- channel, including the lack of voltage dependence and requirement for ATP. Unlike the mini-Cl- channel, the volume-regulated channel in MDR transfectants tends to inactivate at depolarizing potentials and is sensitive to block by verapamil and dideoxyforskolin. Furthermore, the induction of the volume-regulated channel is inhibited by including the anti-mitotic chemotherapeutic agents doxorubicin or vinblastine in the pipette (Gill et al., 1992). Attempts to reproduce several of these findings have been unsuccessful in our lab. For example, control fibroblasts lacking P-glycoprotein express volume-sensitive CIchannels at the same levels as MDRI -transfected fibroblasts (Ehring er al., 1994).The identity of the gene(s) encoding the volume-regulated miniC1- channel remains unknown, although its dependence on ATP suggests that it may belong to the ABC family of proteins. 8. Kinase-Regulated Midi-CI- Channel
Not long after the discovery of volume-regulated CI- channels in lymphocytes, a second type of CI- channel was described, initially at the single-channel level. Using protocols that mimicked a series of experiments performed on epithelial cells (reviewed by Frizzell and Halm, 19901, Chen et af. (1989) characterized an outwardly rectifying Cl- channel of
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moderate conductance (40-50 pS) in leukemic Jurkat T cells and in transformed B lymphoblasts. This channel, which we have termed the “midiCI-” channel for its intermediate conductance, is closely similar to a channel which has been referred to in other cell types as ORDIC (for “outwardly rectifying, depolarization-induced conductance”). The regulation of this channel in both epithelia and lymphocyte cell lines has been investigated extensively, in part because abnormal regulation of this channel in epithelia might contribute to defective C1- secretion in cystic fibrosis patients. A biophysically related channel has also been described in fibroblasts (Bear, 1988).
1. Regulation The midi-CI- channel exhibits a very complex regulation of channel opening (Chen et al., 1989). As with the ORDIC channel in epithelia, different stimuli have been shown to induce channel activity. Patch excision followed by strong depolarization for a prolonged period (> +40 mV for 10 sec to 10 min) is the most reliable way to activate the channel (excision/depolarization protocol). This unphysiological stimulus has been used as a method for determining whether a channel is in fact present in a given patch. Once opened, the lymphocyte midi-CI- channel continues to chatter between open and closed states. In “normal” (non-CF) cells-either Jurkat or control B lymphoblasts-the channel can be induced to open during four different protocols that point toward phosphorylation of a membrane substrate by CAMP-dependent protein kinase: First, in cell-attached patch recordings, channel activity is often observed if cells have been exposed to a permeable cAMP analogue added to the bath (Chen et al., 1989). Second, in whole-cell recordings, prostaglandin E l , which is known to increase cellular cAMP levels, induces a C1- conductance (Maldonado et al., 1991).A cAMPantagonist and a peptide inhibitor of the enzyme block the ability of PGE, to induce this conductance. Third, photorelease of cAMP from a caged cAMP analogue induced a wholecell C1- conductance following flash stimulation (McDonald et al., 1992). Finally, and perhaps most directly, in excised inside-out patch recordings and in whole-cell dialysis experiments, application of purified catalytic subunit of CAMP-dependent protein kinase, along with ATP, promoted channel activity (Chen et al., 1989). Thus, phosphorylation of the channel protein or a closely associated substrate can open the channel. The regulation of channel opening by CAMP-dependent protein kinase appears to be very different in CF cells (Chen et al., 1989). In B lymphoblasts derived from a CF patient, the channel could not be activated by CAMP-dependent protein kinase applied to excised inside-out patches, although it could still be opened by excision/depolarization. Bath exposure of the C F lymphocytes to a permeable cAMP analogue also failed to elicit
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channel activity in cell-attached patches. These initial results raised the possibility of using lymphocytes as a more tractable and accessible cell system in which to investigate the C F defect. Cytosolic [Ca2+lmay be a physiologically important regulator of the lymphocyte midi-CI- channel. Channel activation of cAMP requires a basal level of Ca” (lo-’ or greater), but, once activated, the channel is not directly dependent upon [Ca’+l. Nevertheless, raising [Ca”] to higher levels appears to activate the channel without involving the cAMP pathway. In cell-attached patches and in whole-cell recordings, adding Ca2+ ionophore activated a conductance closely similar or identical to that induced by cAMP (Nishimoto et a/., 1991). A similar conductance was also activated by flash photolysis of intracellular DM-nitrophen (caged Ca”) to elevate cytosolic CaZC(McDonald et al., 1993). As with other activation methods (CAMP,patch excision/depolarization), once the channel is activated it is not sensitive to Ca?+, suggesting that activation by Ca2+is not direct, but regulated by a Ca’+-dependent enzyme. This alternative regulatory pathway appears to be mediated through calciumcalmodulin-dependent (CaM) kinase. A peptide inhibitor containing the autoinhibitory region of CaM kinase partially inhibits the activation of C1conductance by Ca’+ ionophore in whole-cell measurements (Nishimoto et al., 1991). Moreover, in excised inside-out patches, direct application of purified CaM kinase plus ATP elicits C1- channel activity in 100% of the patches with channels, as defined by the excisionldepolarization test. Several aspects of midi-C1- channel regulation have proven to be difficult to reproduce, including regulation by CAMP-dependent protein kinase, regulation by Ca2+ in CF cells, and several detailed biophysical parameters of channel gating and conduction. Differences in cell lines, culture conditions, or experimental protocols may contribute to the variability. Whether changes in C1- conductance during the cell cycle account for some of the variability is controversial. Bubien and colleagues (1990) have reported that Cl- conductance, measured with video imaging of SPQ fluorescence in populations of cells, is highest during the GI phase of the cell cycle. For normal resting B cells isolated from tonsils or peripheral blood, the cell cycle was initiated by addition of monoclonal antibody to the F, portion of surface IgM, along with B-cell growth factor. B-cell lines or activated B cells were synchronized by treating the cells with hydroxyurea to arrest the cells. Cells in Go or in S phase had low C1conductances, while those in the G I phase had uniformly higher C1- conductances. In contrast, G , phase cells from C F patients had very low C1conductances. Gardner and colleagues, using patch-clamp methods, have been unable to confirm the cell-cycle dependence of g,, (McDonald et al., 1992). There may be a different C1- transport system regulated during the cell cycle seen in SPQ imaging that does not show up in patch recordings.
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Alternatively, experimental differences in the method of cell-cycle synchronization may account for the discrepancy. Bubien and colleagues have also observed an increase in CAMP-regulated CI- conductance in C F cells transfected with wild-type cystic fibrosis transmembrane receptor (CFTR) (Krauss et al., 1992a). In these transfectants, cells in GI showed the largest resting and CAMP-dependent C1- conductance, compared with cells in S phase. Comparing imaging and patch-clamp experiments as methods to evaluate Cl- conductance, the cell-cycle dependence seems more pronounced with the imaging assay. SPQ imaging experiments indicate that expression of wild-type CFTR is required for cAMP regulation of the C1- conductance and that the ability of cAMP to increase CIconductance is cell-cycle dependent. In addition, antisense CFTR oligonucleotides inhibit the C1- conductance in G , cells from normal B lymphoblasts (Krauss et al., 1992b). Patch-clamp experiments on freshly isolated, “real” lymphocytes from C F and non-CF individuals will be informative. The role of Ca2+in regulating gcl in CF lymphocytes is disputed. Gardner and colleagues have observed activation of gc, by elevating Ca’+ in both “normal” and CF cell lines (McDonald et al., 1992), whereas Bubien and colleagues (1990) report that neither cAMP nor Ca’+ ionophore caused increased C1- conductance in CF cells. 2. Biophysical Properties and Pharmacology Several biophysical aspects of the midi-C1- channel await further characterization. The CAMP-activated C1- conductance appears to rectify outwardly to a greater degree in patches than in whole-cell measurements. This may reflect activation of multiple populations of channels by cAMP in whole-cell measurements, in addition to the midi-C1- channel that is easily recognized in single-channel patch measurements. The midi-C1channel displays 1O:l C1- selectivity over Na+ (Chen et al., 1989), but so far a thorough study of ion permeation has not been reported. The channel is sensitive to several typical CI- channel blockers, including IAA, NPPB, and SITS (McDonald et al., 1992; Garber, 1992).
3. CI- Channels in Other Cell Types The lymphocyte midi-CI- channel, in most respects, behaves similarly to the outwardly rectifying C1- conductance in epithelia. Both channels are activated by excision/depolarization or by CAMP-dependent protein kinase in normal, but not C F cells (Chen et af., 1989; reviewed by Frizzell and Halm, 1990). In epithelial and lymphoid cells, the ORDIC channel is regulated by more than one kinase: by PKA, PKC, or CaM kinase in epithelia (see Chapter 8, this volume); and by PKA or CaM kinase in Jurkat T cells (Chen et al., 1989; Nishimoto et af., 1991). According
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to Garber ( 1992). channel activation by excisionidepolarization is highly teniperature sensitive in Jurkat T cells: more than twice as many patches show channel activity, with much more rapid induction, at 30°C than at 20°C. The epithelial ORDIC displays a similar temperature dependence (Greger et d . , 19891, as does the maxi-CI- chanel in T lymphocytes (see below; Pahapill and Schlichter, 1992). However, careful investigation of single-channel conductance and open times led Garber to conclude that the biophysical properties of the excision/depolarization-inducedCI- conductance are different in lymphocytes (Garber, 1992). The clearest level of single-channel conductance is smaller in lymphocytes than in epithelial cells studied under identical conditions in the same laboratory. Furthermore. the lymphocyte channel’s open probability is not significantly voltage dependent. In contrast, the epithelial ORDIC has an open probability that is significantly voltage dependent (reviewed by Frizzell and Halm, 1990). Possibly the lymphocyte midi-CI- channel is related. but not structurally identical, to the epithelial ORDIC. The cloning of the CFTR gene and the subsequent reconstitution of the CFTR gene product into planar lipid bilayers has led to reevaluation of the properties and regulation of the midi-CI- channel. Bear t f nl. (1992) concluded that the CFTR itself functions as a kinase-regulated, 8-10 pS, nonrectifying Cl- channel with properties distinct from the midi-CI- channel (Bear et al., 1992). To date, a channel matching the description of the CFTR-Cl- channel has not been described in lymphocytes, although the CFTR is reportedly expressed in lymphocytes. PCR techniques are required to detect the low levels of expression of CFTR transcript in Jurkat cells (McDonald ef a l . , 1992) and in other lymphoid lines (Krauss et ( I [ . , 1992a). Antisense oligonucleotides to the CFTR inhibited expression and abolished the C1- conductance normally present in G, B lymphoblasts, determined by the SPQ fluorescence quench assay (Krauss et i l l . , 1992b). Transfection of CFTR into CF cells restored the cell-cycle and CAMPregulated CI- conductance (Krauss et a / . , 1992a). As suggested for other cell types, the CFTR appears t o regulate the midiC1- channel. It is unclear whether expression levels are high enough for the CI- channel function of the CFTR to contribute significantly to the lymphocyte C1- conductance. It may be that the CFTR regulates C1- channels whose structures have not yet been identified. C. Maxi-Cl- Channels
Extremely large-conductance “maxi”-CI- channels have been described in T and B lymphocytes, thymocytes, and antibody-secreting hybridomacells. These channels can be induced t o conduct by patch excision
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and, once opened, the channel activity is complex, displaying voltagedependent gating kinetics with multiple open and closed states, as well as several subconductance levels. The channel, although normally dormant, is quite abundant and distributed nonuniformly, judging from the probability of observing the channel in excised patches. The regulation and biophysical properties of maxi-CI- channels present several unusual features, as described below. 1. Regulation The highly complex regulation of maxi-CI- induction is poorly understood mechanistically. Two aspects can be distinguished: an initial induction phase that leads to channel activity and a more rapid, voltagedependent channel gating process. Maxi-C1- channel activity can be induced with high frequency by excising an inside-out patch: 65% of patches from hybridoma cells (Bosma, 19891, 50% of patches from human T cells (Schlichter et af., 19901, and 40% of patches from mouse splenic B cells ( F . V. McCann e f a / . , 1989) exhibited channel activity after excision. In most cases, at least two channels per patch were observed, suggesting clustering of channel proteins in the membrane. The channel may be inhibited by cytoplasmic factors; in intact cells channel activity appeared after some delay. Supporting this view, Bosma (1989) found that patches excised into solution containing Mg-ATP had maxi-C1- channels with steeper voltage dependence and a greater tendency to remain in a low subconductance level. In silent patches, prolonged depolarization tended to encourage channel activity. The maxi-C1- channel usually is not observed under normal cellattached or whole-cell recording conditions. However, a low level of channel activity can be induced in these recording configurations by periods of prolonged depolarization, in a manner similar to the ORDIC described above (Bosma, 1989; Schlichter et af., 1990). In macrophages and myotubes, adding the Ca2 ionophore A23 187 increased channel activity in cell-attached patches (Schwarze and Kolb, 1984). However, this method of induction has not been reported in lymphocytes. Once the patch is excised and channel activity initiated, the channel no longer depends upon [Ca”] at the exposed cytoplasmic membrane surface. Channel activity occurs spontaneously in cell-attached recordings at temperatures above 32°C; the channel is more likely to contribute to the membrane’s conductance under physiological conditions (Pahapill and Schlichter, 1992).However, in whole-cell recordings, C1- conductances commensurate with the degree of channel activity in excised patches or in cell-attached patches at body temperature have not been observed. Further investigation is needed to clarify the mechanisms of channel induction. +
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Once induced, the maxi-CI- channel's open probability is strongly dependent upon membrane potential. Most investigators agree that the channel is open near 0 mV and can be closed by either negative or positive potentials, but voltage gating may depend upon the cell type, the patch configuration, the time after excision, and conditioning pulses to varying potentials. Bosma (1989) reports that once the channel is induced, its voltage dependence depends upon whether it is in a cell-attached or an excised patch. In cell-attached patches. the channel's voltage dependence is nearly bell-shaped with an e-fold change in conductance per 10.4 or 15.8 mV, at negative or positive potentials, respectively, with a midpoint near + 10 mV, relative to the resting potential. In excised patches, the channel no longer closes with depolarizing voltage steps and exhibits weaker voltage dependence in the negative range of potentials (e-fold per 25 mV). In human T cells, Schlichter and colleagues (1990) described a steeper voltage dependence in excised patches, with e-fold changes in the open probability per 4.4 or 2.6 mV at negative and positive potentials, respectively. Time constants for channel closure were in the range of 100-150 msec. Pahapill and Schlichter (1992) reported that the channel's voltage dependence is influenced by both the patch configuration and the temperature. In cell-attached recordings at room temperature, very few (< 2%) patches displayed maxi-CI- activity, but 69% of previously quiescent patches showed channel activity upon warming to >32"C; upon return to room temperature, channel activity slowly diminished. In warm cellattached patches, maxi-C1- channels lost the ability to close with membrane hyperpolarization. In addition to patch configuration and temperature, conditioning depolarizing pulses allow the channel to be more active at negative potentials (F. V. McCann er al., 1989). 2. Biophysical Properties and Pharmacology For maxi-CI- channel conductance levels, an enormous single-channel conductance of 350-400 pS is the most frequent. The number of subconductance levels observed varies according to cell type and lab. F. V . McCann and colleagues (1989) described four evenly spaced levels of conductance that can interconvert in murine B cells, while Schlichter and colleagues (1990) saw uniform sublevels of -45 pS in human T cells. In hybridoma cells, Bosma ( 1989) noted four nonuniformly distributed subconductance levels and a supraconductance level, in addition to the 400-pS conductance. This most frequent conductance sublevel saturates at 580 pS as [Cl-1 is raised, with a K , of 120 mM, suggesting weak binding interactions with sites in the pore (Schlichter et al., 1990). Channel selectivity favors anions over cations by at least 10 : 1 (F. V. McCann et al., 1989; Schlichter et al., 19901, but the channel is promiscu-
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ous in choosing anions: even large anions such as aspartate permeate rather freely. F. V. McCann et NI. (1989) report a PCI/Paspartate of 1.25, while Schlichter’s group find a value of about 12. The selectivity sequence determined from measured reversal potentials in human T-cell patches, according to Schlichter and colleagues (1990) is I (1.38) > NO, ( I . 14) > Br (1.04) > CI- (1) > H,PO,/HPO, > F (0.57) > isethionate (0.56) > HC03(0.56) > SO, (0.49) > propionate (0.30) > gluconate (0.29) > aspartate (0.08). Bosma’s (1989)selectivity sequence in hybridoma cells differed somewhat: F (1.25) > I (1.18) > SCN (1.1) > Br (1.07) > CI- (1.0) > glucuronate (0.78) > NO, (0.68) > aspartate (0.62). The pharmacological sensitivity of maxi-CI- channels in lymphocytes has not been extensively investigated. Bosma (1989) reports that SITS, applied internally, blocks the channel with a K j of 5 mM at 0 mV; the voltage dependence indicates a binding site at an electrical distance 37% across the membrane field. DIDS was fivefold less potent; 1 mM 9-AC had no effect. Zn*+or Ni2+(1 mM) added internally produced a reversible, voltage-dependent block (Schlichter et al., 1990).
3. Comparison with CI- Channels in Other Cell Types Similar maxi-CI- channels are present in macrophages. skeletal muscle, Schwann cells, hippocampal neurones, and a variety of epithelial cells (reviewed in Chapter 8, this volume). The molecular configuration of the maxi-CI- channel may be related to bacterial porin, the structure of which has been resolved to 1.8 A (Schulz, 1993). The large conductance and voltage-dependent gating are properties shared by a voltage-dependent anion channel (VDAC) of the outer mitochondria1 membrane; VDAC’s tertiary structure resembles that of porin from gram-negative bacteria (Mannella et al., 1992). Interestingly, a porin-like molecule is present in the plasma membrane of lymphocytes (Thinnes, 1992).Following reconstitution into planar lipid bilayers, the lymphocyte porin exhibits properties similar to those of the maxi-CI- channel (Benz et al., 1992).
N. FUNCTIONAL ROLES OF CI- CHANNELS A. Contribution of fcrto Resting Potential
Ion channels can initiate or modulate functional responses of T and B cells by altering the membrane potential and by gating the flow of specific ions across the plasma membrane. Normally, in a quiescent lymphocyte with low cytosolic [Ca2+],the membrane potential is primarily established by voltage-gated K + channels, in particular by the type n channel encoded
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by Kv1.3 (Cahalan et a / . , 1985; Grinstein and Smith, 1990; Freedman er d., 1992; Leonard et al., 1992). Blocking type n channels usually results in membrane depolarization; murine T cells are an exception: their membrane potential is governed by an electrogenic Na+/K' pump (Ishida and Chused, 1993). K + channel expression is extraordinarily low in mature, resting CD4+ and CD8+ T cells from mice-only 5-10 K(V) channels per cell (DeCoursey et a / . , 1987b; Lewis and Cahalan, 1988). Human T cells typically express about 500 K(V) channels per cell, and, of these, a few open channels suffice to maintain the resting potential. If K + channels are blocked, the resulting membrane depolarization limits Ca?+ entry through mitogen-regulated Ca2+channels (Grissmer et a / . , 1992b; Lin et d.,1993). Do CI- ions contribute to the membrane potential and thereby modulate functional responses? Here, the answer is not as straightforward. Available evidence suggests that there is a degree of CI- permeability which keeps the cells depolarized away from the K equilibrium potential ( Wilson and Chused, 1985). The CI- concentration inside T lymphocytes is 30-40 mM. implying an equilibrium potential for C1- of -30 to -40 mV ( Felber and Brand, 1982).Even rather bulky organic anions such as aspartate can permeate the C1- channels described above. Thus, the reversal potential for the CI- channels under physiological conditions may be closer to 0 mV than the equilibrium potential for C1-. In any event, if C1- channels open, the membrane potential depolarizes. +
B. Mitogenesis Cl- channels may act during mitogenic activation and in the killing of target cells by cytotoxic T lymphocytes and natural killer cells. The CIchannel blockers SITS and DIDS inhibit target cell lysis by cytotoxic T cells or NK cells (Gray and Russell, 1986; Prochazka et al., 1988). Furthermore, treatment with DIDS (but not SITS) or removal of external C1- inhibits antibody-stimulated Ca2+influx (Rosoff et al., 1988). Possibly C1- channels influence cell proliferation by upregulating, for example, as seen in B-lymphoblastoid cells during the cell cycle (Bubien et af., 1990). Despite these tantalizing findings, the role of C1- channels in lymphocyte activation remains unclear, primarily because highly potent and selective blockers for these channels are not available. In mast cells, a CAMP-dependent C1- conductance opens during stimuli that result in degranulation (Penner et al., 1988). The opening of Clchannels may facilitate Ca2+influx by maintaining a negative membrane potential. Mast cells lack K" channels and are highly susceptible to depo-
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larization. In contrast, lymphocytes generally express both K(V) and K(Ca) channels; these channels maintain a negative membrane potential in both the resting and activated state. If C1- channels were to open in lymphocytes, the membrane potential would depolarize rather than hyperpolarize. As discussed above, depolarization inhibits both Ca2+influx and subsequent gene expression leading to cell proliferation (Grinstein and Smith, 1990; Leonard et al., 1992; Freedman el al., 1992). Might opening C1- channels be one mechanism for depressing immune responses‘? Agents such as PGE, or PGE2 that elevate cAMP levels can suppress mitogenic signaling in lymphocytes (Coffey and Hadden, 1985; Kammer, 1988; Bastin et al., 1990; Maldonado et af., 1991). Perhaps opening kinase-regulated C1- channels depolarizes the membrane potential, thereby suppressing mitogen-stimulated Ca2+ infux. Using a lac-2 reporter gene construct driven by the interleukin 2 response element which binds the nuclear factor of activated T cells (NF-AT), Negulescu and Cahalan ( 1994)followed Ca2+signals (induced by T-cell receptor stimulation) that lead to gene expression in single cells. Adding a permeable cAMP analogue suppressed both [Ca”] signals and gene expression in response to T-cell receptor engagement. Thapsigargin, a microsomal CaATPase inhibitor, leads to Ca2+ influx. The resultant cytosolic [Ca’+] level can be “clamped” to varying, stable levels, by altering the ionic gradients of K + and Ca2+,thus bypassing receptors and pre-Ca2+elements of signal transduction. Thapsigargin protocols have made it possible to determine quantitatively the Ca2+dependence of gene expression in single cells. Adding a permeable cAMP analogue inhibited NF-AT-driven interleukin-2 gene expression at both pre- and post-Ca2+steps. Ca2+oscillations induced by T-cell receptor engagement were blocked by CAMP, and gene expression was suppressed, even when [Ca”] was artificially elevated using thapsigargin (Negulescu and Cahalan, 1994). The action of kinase-regulated C1- channels could partly explain inhibition of Ca2+ signaling by cAMP analogues. C. Volume Regulation
Cell swelling as a consequence of osmotic challenge induces RVD, as C1-, K + , and water leave cells via separate, conductive pathways (Grinstein et a / . , 1982; Sarkadi et a / . , 1984a,1985). Cahalan and Lewis (1987,1988)and Deutsch and Lee (1988) have proposed that cell swelling activates mini-CI- channels, resulting in membrane depolarization and the consequent activation of K( V ) channels. According to this hypothesis, the opening of CI- channels provides the initial trigger for RVD; the
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resulting depolarization opens K(V channels. CI- and K' conductances become simultaneously active, allowing CI- and K' to leave the cell. Water follows the osmolytes, bringing cellular volume back toward normal. The mini-CI- channel is an attractive candidate as the RVD trigger because it is opened by cell swelling. Furthermore, the channel's sequence of ion selectivity parallels the cell's ability to volume regulate in solutions containing different anions. In addition. pharmacological agents that block the rnini-CI- channels also inhibit RVD (reviewed in Cahalan and Lewis, 1988; Lewis et al., 1993). The type n K(V) channel, encoded by Kv1.3. could mediate K" efflux during RVD for three reasons: pharmacology, voltage dependence. and cellular distribution. First, agents that are known to block type n K' channels inhibit 86Rb or 42K fluxes induced by hypotonicity (Chandy r t al., 1984; Sarkadi et al., 1985; DeCoursey at al., 1985: Sands et al., 1989; Grinstein and Smith, 1990). Second, according to the CI- trigger hypothesis for RVD (Cahalan and Lewis, 1988: Deutsch and Lee, 1988). the voltage dependence of type n channels allows them to open during the depolarization induced by C1- channel activation. Third, the expression of type n channels parallels the ability of particular cells to volume regulate. For example, human B lymphocytes have fewer type n K + channels than do T cells and volume regulate less effectively (Deutsch et al., 1986). An interleukin-2-dependent T-cell line undergoes RVD in parallel with the expression levels of type n channels (Lee et nl., 1988). By transfecting the Kv1.3 gene into a lymphoid cell (CTLL) lacking both K(V) channels and the ability to volume regulate, Deutsch and Chen (1993) have further tested Kv1.3 as a mediator of the K' efflux limb of RVD. Transfected cells expressing Kvl.3 (but not Kv3. I ) acquired the ability to regulate volume in response to hypotonic challenge, nicely confirming the hypothesis that type n channels encoded by Kvl.3 carry K + efflux during RVD. V. SUMMARY AND PROSPECTS
Patch-clamp techniques have been instrumental in identifying at least three types of C1- channel in lymphocytes, categorized according to their single-channel conductances as mini-, midi-, and maxi-CI-channels. These channels are normally closed in the plasma membrane of quiescent and proliferating cells, but are among the most abundant channels found in lymphocytes. Channel regulation is complex. The opening of each channel subtype depends upon at least two factors: ATP and cell swelling for the mini-CI- channel, phosphorylation or excision/depolarizationfor the rnidiC1- channel, and excision and voltage for the maxi-Cl- channel. Fascinat-
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ing questions remain. For dedicated patch clampers: What factors determine the ion permeation properties which enable relatively bulky anions to pass through both low- and high-conductance channels? Mechanistically, how do channels open? For persistent molecular biologists: Do any of the C1- channels seen in patch-clamp experiments coincide with any known C1- channel gene products? Having reviewed the data, we must conclude that the molecular identity of all three lymphocyte CI- channels is still unknown. For tenacious cell physiologists and immunologists: What functional roles are played by the lymphocyte C1- channels? Rapid answers to these questions may depend upon the development of highly potent and selective C1- channel blockers. Perhaps the world of toxins may yet provide such ligands, as the recent characterization of chlorotoxin from scorpion venom promises (DeBin et al., 1993).
References Amigorena, S .. Choquet. D.. Teillaud. J. L.. Korn. H.. and Fridman. W. H. (1990). Ion channel blockers inhibit B cell activation at a precise stage of the G I phase of the cell cycle. J . Immrrnol. 144, 2038-2045. Bastin, B.. Payet, M . C . , and Dupuis. G. (1990). Effects of modulators of adenylyl cyclase on interleukin-2 production. cytosolic Ca'+ elevation. and K' channel activity in Jurkat T cells. CPII. lt?f/nlttl(J/. 128, 385-399. Bear. C. E. (1988). Phosphorylation-activatedchloride channels in human skin fibroblasts. FEBS Lett. 237, 145-149. Bear, C. E.. Li. C., Kartner, N.. Bridges, R. J.. Jensen. T. J.. Ramjeesingh. M.. and Riordan, J. R. (1992). Purification and functional reconstitution of the cystic fibrosis transmembrane conductance regulator (CFTR). Cell (Cambridge, Mass.) 68, 809-818. Benz. R., Maier, E.. Thinnes. F. P., Goetz, H.. and Hilschmann. N . (1992). The channel properties of the human B-lymphocyte membrane-derived "porin 3 I HL" are similar to those of mitochondria1 porins. Biol. Chem. Hoppe-Seyler 373,295-303. Block, M. L., and Moody, W. J. (1990). A voltage-dependent chloride current linked to the cell cycle in ascidian embryos. Science 247, 1090-1092. Bosma. M. M. (1989). Anion channels with multiple conductance levels in a mouse B lymphocyte cell line. J . Physiol. (London)410, 67-90. Bubien. J. K.. Kirk, K. L., Rado, T. A.. and Frizzell. R. A. (1990). Cell cycle dependence of chloride permeability in normal and cystic fibrosis lymphocytes. Science 248,1416-1419. Cahalan, M. D.. and Lewis, R. S. (1987). Ion channels in T lymphocytes: Role in volume regulation. J . Cen. Physiol. 90, 7a. Cahalan, M. D., and Lewis. R. S. (1988). Role of potassium and chloride channels in volume regulation by T lymphocytes. In "Cell Physiology of Blood" (R. Gunn and J. Parker, eds.), pp. 281-301. Rockefeller Univ. Press, New York. Cahalan, M. D., Chandy, K. G., DeCoursey. T. E.. and Gupta, S . (1985). A voltage-gated K t channel in human T lymphocytes. J . Physiol. (London)358, 197-237. Cahalan. M. D.. Chandy, K. G., andGrissmer, S . (1992).Potassiumchannelsindevelopment, activation, and disease in T lymphocytes. Curr. Top. Membr. 39, 357-394. Chandy, K. G., DeCoursey, T. E.. Cahalan, M. D., McLaughlin, C.. and Gupta. S. (1984). Voltage-gated potassium channels are required for human T lymphocyte activation. J . Exp. Med. 160, 369-385.
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Chandy. K. G.. DeCoursey. T. E.. Fischbach. M . . Talal. N.. Cahalan. M. D.. and Gupta. S . (19861. Altered K' channel expression in abnormal T lymphocytes from mice with the lpr gene mutation. S&nce 233, 1197-1200. Chandy. K. G.. Cahalan. M. D.. and Grissmer, S. (1990). Autoimmune diseases linked to abnormal K ' channel expression in double-negative CD4- CD8- T cells. Errr. J . Imrnrrno/. 20, 747-751.
Chen, J. H.. Schulman. H., and Gardner. P. (1989). A CAMP-regulated chloride channel in lymphocytes that is affected in cystic fibrosis. Science 243, 657-660. Cheung. R . K.. Grinstein. S . . Dosch. H.-M.. and Gelfand. E. W. (1982). Volume regulation by human lymphocytes: Characterization of the ionic basis for regulatory volume decrease. J . Cell. Physiol. 112, 189-196. Coffey. R. G.. and Hadden. J. W. (1985). Neurotransmitters. hormones. and cyclic nucleotides in lymphocyte activation. Fed. Proc.. Fed. Am. Soc. Exp. Biol. 44, 112-117. DeBin. J. A,. Maggio, J. E.. and Strichartz. G. R . (1993). Purification and characterization of chlorotoxin. a chloride channel ligand from the venom of the scorpion. Am. J . Ph.vsiul. 264, C361-C369.
DeCoursey. T. E.. Chandy. K. G.. Gupta. S.. and Cahalan. M . D. (1984). Voltage-gated K' channels in human T lymphocytes: a role in mitogenesis? Natrrre (London)307, 465-468.
DeCoursey. T. E.. Chandy. K. G.. Gupta. S . . and Cahalan. M. D. (1985). Voltage-dependent ion channels in T lymphocytes. J . Nerrroimmirnol. 10, 71-85. DeCoursey. T. E.. Chandy, K . G.. Gupta, S.. and Cahalan. M. D. (1987a). Two types of potassium channels in murine T lymphocytes. J . Gen. Physiol. 89. 379-404. DeCoursey. T. E.. Chandy. K. G.. Gupta, S . , and Cahalan. M. D. (1987b3. Mitogen induction of ion channels in murine T lymphocytes. 1. Gen. Physiol. 89, 405-420. Deutsch. C., and Chen, L.-Q. (1993). Heterologous expression of specific K + channels in T lymphocytes: Functional consequences for volume regulation. Proc. N u f l .A c ~ i dSci. . U.S.A. 90, 10036-10040.
Deutsch. C.. and Lee, S. C. (1988). Cell volume regulation in lymphocytes. R e n d Phvsiol. Biochern. 11 (3-5). 260-276. Deutsch. C., Krause, D., and Lee, S. C. (1986). Voltage-gated potassium conductance in human T lymphocytes stimulated with phorbol ester. J . Phvsiol. (London)372,405-423. Doroshenko. P. ( 1991). Second messengers mediating activation of chloride current by intracellular GTPyS in bovine chromaffin cells. J . Phvsiol. (London) 436, 725-738. Doroshenko. P. and Neher, E. ( 1992). Volume-sensitive chloride conductance in bovine chromaffin cell membrane. J . Phvsiol. (LOndOt7) 449, 197-218. Doroshenko. P.. Penner, R . . and Neher, E. (1991). Novel chloride conductance in the membrane of bovine chromaffin cells activated by intracellular GTPyS. J . Physiol. (London) 436, 71 1-724.
Ehring. G.. Osipchuk. Y., and Cahalan, M. D. (1994). Volume-activated chloride channels in drug-sensitive and -resistant cell lines. Biophvs. J . 66, A412. Estacion, M. (1991). Characterization of ion channels seen in subconfluent human dermal fibroblasts. J . Physiol. (London) 436, 579-601. Felber. S. M.. and Brand, M. D. (1982). Factors determining the plasma membrane potential of lymphocytes. Biochem. J . 204, 577-585. Freedman, B. D., Price, M. A.. and Deutsch. C. J. (1992). Evidence for voltage modulation of IL-2 production in mitogen-stimulated human peripheral blood lymphocytes. J . Irnrnuno/. 149, 3784-3794.
Frizzell, R . A., and Halm. D. R . (1990). Chloride channels in epithelial cells. Curr. Top. Mernbr. Transp. 31, 247-282.
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Garber. S. S. (1992). Outwardly rectifying chloride channels in lymphocytes. J . Membr. Biol. 127, 49-56. Gill. D. R.. Hyde, S. C., Higgins. C. F.. Valverde. M. A.. Mintenig. G. M.. and Sepulveda. F. V. (1992). Separation of drug transport and chloride channel functions of the human multidrug resistance P-glycoprotein. Cell (Cambridxe. Mass.) 71, 23-32. Gray. L. S . . and Russell. J. H. (1986). Cytolytic T lymphocyte effector function requires plasma membrane chloride flux. J . Irnmitnol. 136, 3032-3037. Greger, R.. Kunzelmann. K.. and Gerlach. L. (1989). Mechanisms of chloride transport in secretory epithelia. Ann. N.Y. Acrrd. Sci. 574,403-415. Grinstein. S., and Smith. J. D. (1990). Calcium-independent volume regulation in human lymphocytes: Inhibition by charybdotoxin. J . Gen. Phvsiol. 95, 97-120. Grinstein. S .. Clarke, C. A., Dupre. A.. and Rothstein. A. (1982). Volume-induced increase of anion permeability in human lymphocytes. J . Geri. Phvsiol. 80, 801-823. Grinstein, S . . Rothstein, A.. Sarkadi. B., and Gelfand. E. W. (1984). Responses of lymphocytes to anisotonic media: Volume-regulating behavior. Am. J . Physiol. 246, C204-C215. Grissmer. S . . Cahalan. M. D.. and Chandy. K. G. (1988). Abundant expression of type I K channels. a marker for lymphoproliferative diseases? J . ftnmunol. 141, 1137-1 142. Grissmer. S . , Dethlefs. B . . Wasmuth. J.. Goldin. A. L.. Gutman. G. A,. Cahalan. M. D.. and Chandy. K. G. (1990a). Expression and chromosomal localization of a lymphocyte K’ channel gene. Proc. Natl. Acad. Sci. U.S.A. 87, 941 1-9415. Grissmer. S .. Hanson. D.. Natale. P.. Cahalan. M. D.. and Chandy. K. G. (1990b). CD4CD8-T cells from mice with collagen arthritis display aberrant expression of type I K + channels. J . fnirnunol. 145, 2105-2109. Grissmer. S . . Ghanshani. S.. Dethlefs. B . . McPherson. J. D.. Wasmuth. J. J.. Gutman, G. A., Cahalan, M. D., and Chandy, K. G. (1992a).The Shaw-related potassium channel gene. Kv3.1. on human chromosome 11. encodes the type I K t channel in T cells. J . Biol. Chern. 267, 20971-20979. Grissmer. S .. Lewis, R. S., and Cahalan. M. D. (1992b). Ca’+-activated K t channels in human leukemic T cells. J . Gen. Physiol. 99, 1-23. Grissmer. S ., Nguyen, A. N., and Cahalan. M. D. (1993). Ca’t-activated K + channels in resting and activated human T cells. J . Gen. Physiol. 102, 601-630. Grunder, S.. Thiemann, A,, Pusch, M., and Jentsch. T. J. (1992). Regions involved in the opening of CIC-2 chloride channel by voltage and cell volume. Nature (London) 360, 759-762. Hoth. M.. and Penner, R. (1992). Depletion of intracellular calcium stores activates a calcium current in mast cells. Nature (London)355, 353-356. Ishida. Y . , and Chused, T. M. (1993). Lack of voltage-sensitive potassium channels and generation of membrane potential by sodium potassium ATPase in murine T lymphocytes. J . Irnrnunol. 151, 610-620. Kammer, G. M . (1988). The adenylate cyclase-CAMP-protein kinase A pathway and regulation of the immune response. Irnrnunol. Todav 9, 222-229. Krauss, R. D., Bubien, J. K., Drumm. M . L.. Zheng. T.. Peiper. S. C., Collins, F. S . . Kirk. K. L., Frizzell, R. A., and Rado, T. A. (1992a). Transfection of wild-type CFTR into cystic fibrosis lymphocytes restores chloride conductance at G Iof the cell cycle. EMBO J . 11, 875-883. Krauss, R. D., Berta, G., Rado, T. A.. and Bubien, J . K. (1992b). Antisense oligonucleotides to CFTR confer a cystic fibrosis phenotype on B lymphocytes. Am. J . Phvsiol. 263, C1147-CI151. Kubo, M.. and Okada. Y . (1992). Volume-regulatory CI--channel currents in cultured human epithelial cells. J . Physiol. (London)456, 351-371. +
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Kuno. M.. and Gardner. P. (1987). Ion channels activated by inositol I ,4.5-trisphosphate in plasma membrane of human T lymphocytes. Ntttrrre (Lonclon) 326, 301-304. Lee. S. C . . Price. M.. Prystowsky. M. B.. and Deutsch. C. (1988). Volume response of quiescent and interleukin 2-stimulated T lymphocytes to hypotonicity. A m . J . Phvsiol. 254, C286-C296. Leonard. R. J.. Garcia. M. L.. Slaughter, R. S.. and Reuben. J. P. (1992). Selective blockers of voltage-gated K t channels depolarize human T lymphocytes: Mechanism of the antiproliferative effect of charybdotoxin. Proc,. Nutl. A ~ u d . Sci. U . S . A . 89, 10094- 10098. Lewis. R. S.. and Cahalan. M. D. (1988). Subset-specific expression of potassium channels in developing murine T lymphocytes. Sciericr 239, 771-775. Lewis. R. S.. and Cahalan. M. D. (1989). Mitogen-induced oscillations of cytosolic Ca” and transmembrane Ca’+ current in human leukemic T cells. Cell Rcyirl. 1, 99-112. Lewis. R. S .. and Cahalan. M. D. (1990). Ion channels and signal transduction in lymphocytes. Annrr. Rev. Ph.vsiol. 52, 415-430. Lewis. R. S.. Ross, P. E., and Cahalan, M. D. (1993). Chloride channels activated by osmotic stress in T lymphocytes. J . Gen. Pl7psiol. 101, 801-826. Lin. C. S .. Boltz. R. C.. Blake. J. T.. Nguyen. M., Talento. A.. Fischer. P. A.. Springer. M. S . , Sigal, N. H., Slaughter. R . S . . and Garcia. M. L. (1993). Voltage-gated potassium channels regulate calcium-dependent pathways involved in human T lymphocyte activation. J. Exp. Med. 177, 637-645. Mahaut-Smith, M. P.. and Mason, M. J. (1991). Ca’+-activated K t channels in rat thymic lymphocytes: Activation by concanavalin A . J. Physiol. (London)439, 5 13-528. Mahaut-Smith, M. P.. and Schlichter. L. C . (1989). Ca?+-activatedK t channels in human B lymphocytes and rat thymocytes. J. Physiol. (London)415,69-83. Maldonado, D., Schumann, M., Nghiem, P., Dong, Y.. and Gardner. P. (199I ). Prostaglandin E, activates a chloride current in Jurkat T lymphocytes via CAMP-dependent protein kinase. F A S E B J . 5, 2965-2970. Mannella, C. A., Forte, M., and Colombini, M. (1992). Toward the molecular structure of the mitochondria1 channel, VDAC. J . Bioenerg. Biomembr. 24, 7-19. Matteson, D. R., and Deutsch, C. (1984). K + channels in T lymphocytes: A patch-clamp study using monoclonal antibody adhesion. Natrrre (London)307, 468-47 I . Matthews, G.. Neher, E., and Penner, R. (1989).Chloride conductance activated by external agonists and internal messengers in rat peritoneal mast cells. J . Physiol. (London)418, I3 I - 144. McCann, F. V., McCarthy. D. C.. Keller, T. M.. and Noelle, R. J . (1989). Characterization of a large conductance non-selective anion channel in B lymphocytes. Cell. Signal. 1, 3 1-44. McCann, J. D., Li, M., and Welsh, M. J. (1989). Identification and regulation of whole cell chloride currents in airway epithelium. J. Gen. Physiol. 94, 1015-1036. McDonald, T. V., Nghiem, P. T., Gardner. P.. and Martens, C. L. (1992). Human lymphocytes transcribe the cystic fibrosis transmembrane conductance regulator gene and exhibit CF-defective CAMP-regulated chloride current. J. B i d . Chem. 267,3242-3248. McDonald. T.V., Premack. B. A,. and Gardner, P. (1993). Flash photolysis ofcaged inositol 1.4.5-trisphosphate activates plasma membrane calcium current in human T cells. J. Biol. Chem. 268, 3889-3896. Negulescu, P., and Cahalan. M. D. (1994). lntracellular calcium dependence of gene expression in single T lymphocytes. Proc. Natl. Acad. Sci. U.S.A.91, 2873-2877. Nishimoto, I . , Wagner, J . A., Schulman, H . , and Gardner, P. (1991). Regulation of CIchannels by multifunctional CaM kinase. Neitron 6 , 1-20.
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Pahapill, P. A , . and Schlichter. L. C. (1992). CI- channels in intact T lymphocytes. J . Mernhr. B i d . 125, 171-183. Partiseti. M.. Choquet. D., Diu. A.. and Korn, H. (1992). Differential regulation of voltageand calcium-activated potassium channels in human B lymphocytes. J . fmmrrml. 148, 336 1-3368. Partiseti. M.. Korn. H.. and Choquet, D. (1993). Pattern of potassium channel expression in proliferating B lymphocytes depends upon the mode of activation. J . fmmimol. 151, 2462-2470. Penner. R., Matthews. G . , and Neher. E. (1988). Regulation of calcium influx by second messengers in rat mast cells. Nutrrre ( L o ~ h n334, ) 499-504. Premack. B. A , . and Gardner. P. (1991). Role of ion channels in lymphocytes. J . Clin. Iin~nrmol.11, 225238. Prochazka. G.. Landon. C.. and Dennert. G. (1988).Transmembrane chloride flux is required for target cell lysis but not for Golgi reorientation in cloned cytolytic effector cells. J . Inimrrnol. 141, 1288-1294. Rosoff. P. M.. Hall. C.. Gramates. L. S. .and Terlecky. S . R. ( 1988).4.4'-diisothiocyanatostilbene-2.2'-disulfonic acid inhibits CD3-T cell antigen receptor-stimulated Ca" influx in human T lymphocytes. J . B i d . Chrm. 263, 19535-19540. Ross. P., Garber. S . . and Cahalan. M. D. (1994). Membrane chloride conductance and capacitance in Jurkat T lymphocytes during osmotic swelling. Biopkvs. J . 66, 169-178. Sands. S. B.. Lewis. R . S . . and Cahalan. M. D. (1989). Charybdotoxin blocks voltage-gated K + channels in human and murine T lymphocytes. J . Gen. Physiol. 93, 1061-1074. Sarkadi. B.. Mack. E . . and Rothstein. A. (1984a). Ionic events during the volume response of human peripheral blood lymphocytes to hypotonic media. I . Distinctions between volume-activated CI- and K' conductance pathways. J . Gen. Physiol. 83, 497-512. Sarkadi. B., Mack. E.. and Rothstein. A. (l984b). Ionic events during the volume response of human peripheral blood lymphocytes to hypotonic media. 11. Volume- and timedependent activation and inactivation of ion transport pathways. J . Gen. Phvsiol. 83, 513-527. Sarkadi, B.. Cheung. R.. Mack, E.. Grinstein. S.. Gelfand, E. W., and Rothstein. A. (1985). Cation and anion transport pathways in volume regulatory response of human lymphocytes to hyposmotic media. Am. J . Physiol. 248, C480-C487. Schlichter, L. C.. Grygorczyk. R., Pahapill, P. A , . and Grygorczyk, C. (1990). A large, multiple-conductance chloride channel in normal human T lymphocytes. Pjuegers Arch. 416, 413-421. Schulz. G. E. (1993). Bacterial porins: Structure and function. Curr. @in. CelI B i d . 5, 701-707. Schwarze. W.. and Kolb, H.-A. (1984). Voltage-dependent kinetics of an anionic channel of large unit conductance in macrophages and myotube membranes. Pjiregers Arch. 402, 281-291. Solc. C . K., and Wine. J . J . (1991). Swelling-induced and depolarization-induced CI--channels in normal and cystic fibrosis epithelial cells. A m . J . Pliysiol. 261, C658-C674. Stoddard. J . S.. Steinbach. J . H.. and Simchowitz. L. (1993). Whole cell CI--currents in human neutrophils induced by cell swelling. A m . J . Physiol. 265, C156-CI65. Thiemann, A , , Grunder, S . . Pusch. M.. and Jentsch. T. J . (1992). A chloride channel widely expressed in epithelial and non-epithelial cells. Narrrre (London)356, 57-60. Thinnes, F. P. (1992). Evidence for extra-mitochondria1 localization of the VDAClPorin channel in eucaryotic cells. J . Bioenerg. Biomembr. 24, 71-75. Tseng. G.-Y. (1992). Cell swelling increases membrane conductance of canine cardiac cells: Evidence for a volume-sensitive CI- channel. A m . J . Phvsiol. 262, C1056-CI068.
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Valverde. M. A.. Diaz, M.. and Sepulveda. F. V. ( 1992). Volume-regulated chloride channels associated with the human multidrug-resistance P-glycoprotein. Natrirr (London) 355, 830-833. Wilson. H. A., and Chused. T. M. (1985). Lymphocyte membrane potential and Ca2+sensitive potassium channels described by oxonal dye fluorescence measurements. J . Cell. Physiol. 125, 72-81. Worrell. R. T.. Butt, A. G., Cliff, W. H.. and Frizzell. R. A. (1989). A volume-sensitive chloride conductance in human colonic cell line T84. Am. J . Physiol. 256, C 1 I I I-ClI19. Zweifach, A.. and Lewis. R. S. (1993). Mitogen-regulated Ca’+ current of T lymphocytes is activated by depletion of intracellular Ca’+ stores. Proc. Nut/. Acud. Sci. U . S . A . 90, 6295-6299.
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CHAPTER 6
Chloride Channels in Skeletal Muscle a n d Cerebral Cortical Neurons Andrew L. Blatz Department of Physiology. University of Texas Southwestern Medical Center at Dallas, Dallas, Texas 75235
I . Introduction 11. Skeletal Muscle Chloride Channels A . Slow and Fast CI Channels in Skeletal Muscle 9. Large-Conductance CI Channels in Skeletal Muscle 111. Non-Transmitter-ActivatedNeuronal Cloride Channels A. Ion Selectivity
B . Single Channel Kinetics C. Block By Quaternary Ammonium Ions IV. Summary References
1. INTRODUCTION
Ion channels selective for chloride ions (Cl) have been found in a variety of mammalian tissues, including muscle, nerve, endocrine and exocrine gland, and epithelium. It is probably not an exaggeration to say that, in fact, all cells contain CI channels. Because of technical difficulties, the study of C1 channels lagged behind that of the cation-selective ion channels, but with the advent of the patch voltage-clamp technique many of these technical problems have been overcome and the C1 channel field has been advancing steadily. In this chapter, I discuss the properties of Cl channels that have been identified at the single-channel level in cells from two excitable mammalian tissues, skeletal muscle and cerebral cortiCitrrenr Topics in Membranes, Volume 42 Copyright 0 1994 by Academic Press, Inc. All rights of reproduction in any form reserved.
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cal neurons. For an excellent, comprehensive review of vertebrate and invertebrate muscle Cl conductances see Bretag ( 1987). II. SKELETAL MUSCLE CHLORIDE CHANNELS Vertebrate skeletal muscle plasma membranes are highly permeable to Cl- (Hodgkin and Horowicz, 1959; Hutter and Noble, 1960; Palade and Barchi, 1977). If this large anion permeability is pharmacologically or genetically reduced, the muscles exhibit hyperexcitability and myotoniclike trains of action potentials (Adrian and Bryant, 1974). This suggests that muscle C1 channels may serve to reduce excitability to a level that maintains the normal one-to-one relationship between nerve impulses and contraction of most skeletal muscle. Although microelectrode voltageclamp techniques have provided some information about the properties of the ion channels underlying this large muscle anion conductance, the electrophysiological properties of the channels underlying the large resting membrane CI conductance have not yet been convincingly demonstrated at the single-channel level. During the search for the channels that give rise to the large resting CI conductance, three Cl channels were demonstrated to be present in muscle-surface membranes; two channels with single-channel conductances of 40-60 pS (with 140 [KCI] on both membrane surfaces), which we called the “fast” and “slow” CI channels; and one channel, called the “megachannel,” with the very large single-channel conductance of about 400 pS under similar conditions (Blatz and Magleby, 1983,1985). A. Slow and Fast CI Channels in Skeletal Muscle.
Two C1-selective ion channels were discovered in tissue-cultured rat skeletal muscle that potentially could contribute to the resting CI conductance (Blatz and Magleby, 1985). Both of these channels were selective for CI and could be active at normal negative membrane potentials. Singlechannel current traces, obtained with the patch-clamp technique (Hamill et al., 1981), for both of these channels are shown in Fig. I . One channel, called the “slow C1 channel” exhibited a single-channel conductance of about 60 pS in the presence of symmetrical (Le., [KCI], = [KClIJ 100 mM KCI, and mean open lifetimes on the order of 10 msec. These slow CI channels were present in only about 2% of excised, inside-out membrane patches and so their properties were not studied in great detail. The “fast CI channel,” on the other hand, was found to be present in
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B
A C 0
-30rnV
C
C
0
0
50 rns FIGURE 1 Fast and slow C1 channels recorded from tissue-cultured rat skeletal muscle using the patch-clamp technique. Single-channel currents were recorded from excised insideout patches of muscle-surface membrane. (A) Fast CI channels recorded at holding potentials of - 30 mV (top) and - 80 mV (bottom) in the presence of 1.6 M [KCI], and 140 mM [KCI],. (B) Slow C1 channels recorded at the same membrane potentials in the presence of I .4mM [KCII,and 100 mM [KCI],. All traces were low-pass filtered at I .6 kHz ( - 3 dB). (Reproduced by copyright permission of the Biophysical Society, Blatz and Magleby. 1985).
most inside-out patches studied. These channels exhibited unitary conductances of about 45 pS in the presence of symmetrical 100 mM KCl and mean open lifetimes on the order of I msec. 1. Ion Selectivity Both the fast and the slow C1 channels were selective for Cl over cations,
but the selectivity was much less than perfect, as shown for the slow C1 channel in Fig. 2. For this experiment the shift in reversal potential for a slow CI channel was measured as the solution bathing the formerly intracellular membrane surface was changed from 100 mM KCI (which was present at the formerly extracellular membrane surface throughout) to I .4 M KCI. As expected, under symmetrical conditions, single-channel currents reversed at 0 mV (not shown). As the [KCl] on the intracellular membrane surface was raised, the reversal potential shifted in a depolarizing direction such that, in the presence of 1.4 M KCI, the single-channel currents shifted from inward to outward at about 35 mV, as expected for a channel that is selective for anions over cations. The magnitude of the observed reversal potential shift is much less than would be expected for perfect discrimination between anions and cations. The Nernst equation predicts that, under the conditions in Fig. 2, currents through a perfectly anion-selective channel would reverse at a potential of 60 mV. The Goldman-Hodgkin-Katz voltage equation can be used to calculate a permeability ratio of K permeability to C1 permeability for the slow Cl channel of 0.2, indicating that slow CI channels are actually fairly permeable to K as well as to Cl. That the nonideal shift in reversal potential
+
+
Andrew L. Blatz
134 A
-n--
4
-
-
-
-
--d
B
-15
FIGURE 2 Cation permeability of the slow CI channel from rat skeletal muscle. (A) Patch-clamp currents from an excised inside-out membrane patch containing a slow CI
channel (open channel level b) and a large-conductance Ca-activated K channel (open channel level c). Level a indicates current level when both channels are closed. Level d indicates current magnitude when both the slow CI channel and the BK channel are open. Bathing solutions: 1.4 M [KCIJi,100 mM [KCI],. Holding potential of - 10 mV. (B) Current-voltage plot for channels in (A). Open symbols represent current-voltage relationship of BK channels recorded in the same patch. Filled squares represent data from the slow CI channel. BK channel extrapolated reversal potential of -60 mV, while the slow CI channels reversed direction at about + 30 mV. (Reproduced by copyright permission of the Biophysical Society, Blatz and Magleby, 1985).
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was not due to errors in solution composition, voltage measurements, or drift was confirmed by the -60 mV shift in reversal potential for a largeconductance Ca-activated K channel (BK channel) that was also present in the same membrane patch. Skeletal muscle BK channels are known to be perfectly selective for cations over anions (Blatz and Magleby, 1984), and so the observed ideal -60-mV reversal potential shift could be used as a valuable control in this experiment. Similar results were obtained using NaCl, suggesting that slow CI channels do not discriminate well between monovalent cations. The relative permeability of the fast C1 channels to anions over cations was also found to be about 0.8 (Blatz and Magleby, 1985). Other “CI channels” seem to be measurably permeant, as measured by reversal potential shifts, to cations (Franciolini and Nonner, 1987). If these CI channels are 20% permeable to cations then one would expect to be able to record single-channel currents carried exclusively by cations but this turns out not to be the case. No currents through fast or slow C1 channels are observed when CI is replaced by impermeant anions (Blatz and Magleby, 1985, and unpublished observations). Franciolini and Nonner (1987) proposed a molecular solution for this phenomenon in a neuronal C1 channel which invokes a cation binding site located within the channel pore. When a cation is bound to this site, the channel allows the flux of anions, but when the bound cation leaves the channel it does so as an ion pair coupled to an anion and therefore carries no current. Permeability measurements using reversal potential shifts would still indicate a significant cation permeability, even though conductance measurements would demonstrate no current carried by the cation.
2. Single-Channel Kinetics Before the advent of single-channel recording techniques like patch clamp and lipid bilayer methods, it could only be speculated that ion channels open and close as rectangular pulses of current. Only when these modern electrophysiological approaches arrived was it actually possible to confirm these speculations. Analysis of the durations and amplitudes of these pulses of currents gives us a valuable window into the underlying conformational rearrangements undergone by ion channel proteins. One of the CI channels in skeletal muscle, the fast C1 channel, has proven to be a valuable resource for the study of ion channel kinetic behavior. These channels exhibit many features that are desirable for kinetic studies. The amplitude of the single-channel currents is large and can be increased further by making measurements in the presence of large CI gradients and high C1 concentrations (Blatz and Magleby, 1985, 1986b). The channels exhibit few excursions into subconducting states, very much unlike another popular CI-selective channel, the y-amino butyric acid-
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activated C1channel (GABA channel). Fast CI channels can remain active for extended periods without the washout, rundown, or desensitization problems that plague other channels. These properties make the fast CI channel an ideal model for the study of ion channel kinetics. a . Unconditional Dwell Time Distributions. As mentioned above, information about the molecular reaction scheme underlying single fast C1 channel kinetic behavior can be obtained from the durations of the open and closed channel intervals. The first attempt to characterize the kinetic behavior of these channels in terms of underlying reaction schemes used the unconditional distributions of these interval durations (Blatz and Magleby, 1986b). Unconditional distributions are composed of the open and closed interval durations, without regard to their temporal position in the experimental record. In other words, unconditional distributions do not take into account the durations of adjacent open and closed intervals, but assume that the open and closed interval durations are truly not correlated in time. The framework for the analysis of unconditional open and closed interval durations is provided by Colquhoun and Hawkes (1983) and Colquhoun and Sigworth (1983). Using the computational techniques described by these authors as modified by Blatz and Magleby (1985,1986a) to account for the effects of missed events due to filtering, it is possible to determine which kinetic reaction schemes are most likely able to fit the experimental distributions. Using these unconditional distributions, two of which are shown in Fig. 3, Blatz and Magleby (1986b) found that, in fact, a variety of kinetic models were able to fit the experimentally observed distributions and that the unconditional distributions could not identify the best one. Although some models were better fits to the experimental data than were others, an unequivocal determination of the absolute best model was impossible based on analysis of the unconditional distributions. Although the assignment of the best kinetic scheme was not possible, Blatz and Magleby (1986b)were able to determine that, whatever model was correct, it must contain at least two open kinetic states and at least five closed kinetic states. It was the connections between these seven states that was unclear.
6 . Conditional Distributions: Adjacent State Analysis. Much more information is contained in the open and closed interval durations then simply the individual durations. The temporal sequence of these open and closed events contains this extra information. When the sequence of interval durations is preserved, the resultant distributions are called conditional distributions. Thus, with conditional distributions one can look at all open intervals that occurred adjacent to short-duration closed
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intervals, open intervals next to intermediate-duration closed intervals, the durations of open intervals that occurred next to long closed events, etc. In order to maintain a sufficient number of events in each distribution it is necessary to compare, for example, open intervals that occurred next to ranges of closed event durations rather than look at open intervals next to closed events of a specific duration. Using these conditional distributions, the “connectivity” of the underlying kinetic states can be assessed, as well as the absolute numbers of states. Unconditional distributions can be analyzed in a manner such that many fast Cl channel models that are acceptable based on the unconditional distributions can be ruled out based on the conditional distributions. Blatz and Magleby (1989) divided fast C1 channel shut interval durations into several ranges, from those with durations of the order of less than a millisecond, to those with durations of hundreds of milliseconds and analyzed the distributions of open intervals that occurred adjacent to these closed interval ranges. The experimentally observed result is shown in Fig. 4. An “adjacent state” relationship clearly exists between the relative proportion of short and long open interval durations and the durations of adjacent shut intervals. This is manifested as an increase in the relative area of the kinetic open state with the shorter mean lifetime as the mean duration of adjacent closed intervals increases. Thus, the relationship is an inverse one, such that open intervals with shorter mean durations tend to occur next to closed intervals with longer mean durations, and, conversely, open intervals with longer durations tend to occur adjacent to closed intervals with shorter durations. This observation imposes some serious constraints on the interconnections of the seven kinetic states already known to exist for these channels: (1) there must be at least two direct “gateway” transition pathways between the open and closed channel kinetic states, and (2) the open kinetic states with short mean lifetimes must be connected to the closed kinetic states with longer mean lifetimes, and the open kinetic states with longer mean lifetimes must be directly connected with the closed kinetic states with shorter mean lifetimes. Two seven-state kinetic models that fit the unconditional distributions equally well are
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these two models is shown in Fig. 5. It is clear that the linear model (Scheme I ) cannot account for the observed inverse relationship between the durations of the open and closed channel kinetic states. c . Two-Dimensional Distriburions. In reality, the analysis of the conditional distributions of adjacent open and closed interval durations is a special case of a much more general form of distribution analysis that has more recently been applied to the muscle fast C1 channel. The general form of the adjacent state analysis is called two-dimensional distribution analysis. Two-dimensional distribution analysis of the durations of open and closed interval durations allows the use of all of the kinetic information contained in the open and closed interval durations. A drawback to the use of two-dimensional distribution analysis is the difficulty in compensating for the effects of limited time resolution due to filtering. With onedimensional unconditional distributions, several methods are available to partially compensate for the corrupting effects of filtering (Wilson and Brown, 1985; Roux and Sauve, 1985; Blatz and Magleby, 1986a). Magleby and Weiss (1990) developed a sophisticated, computationally intense method of analyzing two-dimensional interval duration distributions that utilizes all of the kinetic information contained in the open and closed interval durations and completely accounts for the effects, not only of missed events due to filtering, but of noise as well. The method developed by Magleby and Weiss (1990) uses brute-force simulation of sequences of open and closed channel events from a given kinetic reaction scheme (such as Schemes I and 11) followed by digital filtering and the addition of actual patch-clamp noise. The simulated data are then compared, using the method of maximum likelihood, to the experimentally observed twodimensional distributions of open and closed interval durations. The parameters of the fit, which are the transition rate constants between the kinetic states, are adjusted and the simulation process is repeated until the best fitting set of rate constants for a particular reaction scheme are obtained. Other combinations of open and closed kinetic states are then compared and, after compensating for different numbers of parameters, the reaction scheme with the greatest likelihood is determined. This method would have been somewhat impractical a few years ago, but now, with the advent of faster (and cheaper) microcomputers, the simulation approach is the preferred approach for determining the kinetic reaction scheme underlying single-channel activity.
3. Voltage Dependence of Muscle Fast CI- Channel Kinetics The currents through most, if not all, ion channels are dependent on the magnitude and sign of the membrane electrical field. The magnitude and direction of the ionic current flowing through all ion channels is, of
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course, related to the driving force on the permeant ions with a driving force equal to the membrane potential minus the electrochemical equilibrium potential given by the Nernst equation. The magnitude of ionic current is also dependent on the kinetic activity of the particular ion channel. Given equal driving forces, the net ionic current is proportional to the percentage of time that an ion channel spends in the open conforma-
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tion. The percentage of time that a channel is open is calculated simply as 100 times the amount of time that the channel is open divided by the total observation time. A more commonly used parameter is called the open probability which is simply the fraction of the total observed time that the channel is in the open state. When a membrane patch contains a single ion channel, the open probability is the percentage of time open divided by 100. When more than one channel is present, the open probability can be estimated from the relative time that zero, one, two, three, or more channels are simultaneously open (Barrett et al., 1982). Fast C1 channels from tissue-cultured rat skeletal muscle exhibit a voltage dependence such that the open probability is low at hyperpolarized membrane potentials and increases as the membrane potential is made more positive (Fig. 6A). The major effect of depolarization is to decrease the mean duration of shut intervals, while the mean open duration increases to a lesser extent (Fig. 6B). From the steady-state voltage dependence of muscle fast Cl channel kinetics, Weiss and Magleby (1990) calculated that a 17 (+4)-mV depolarization produced an e-fold increase in open probability which is equivalent to an “effective gating charge” (Hodgkin and Huxley, 1952; Hille, 1984)of 1.6 & 0.32. This voltage dependence falls between the extremely strong voltage dependence of action potentialgenerating channels such as the rat brain sodium channels (Keller et al., 1986) and the squid axon delayed rectifier K channel (Behrens er al., 1989) and the less voltage-dependent agonist-activated channels such as the GABA-activated Cl channel (Weiss, 1988)and the neuromuscularjunction acetylcholine-activated cation channel (Magleby and Stevens, 1972). B. Large-Conductance CI Channels in Skeletal Muscle
The third C1 channel that was found to be present in the surface membranes of tissue-cultured skeletal muscle exhibited the extremely large single-channel conductance of over 400-pS in symmetrical 140 mM KCI (Blatz and Magleby, 1983). These channels, which we called “megachannels” have some properties which are similar to those of the voltagedependent anion channels (VDAC) found in mitochondria outer membranes (Colombini, 1979). These channels are not restricted to muscle tissue, but have been found in such tissues as rabbit urinary bladder (Hanrahan et al., 1985), mouse macrophage and chicken myotubes (Schwarze and Kolb, 1984), pulmonary epithelia (Schneider et al., 1983, rat Schwann cells (Gray et al., 19841, and rat mast cells (Lindau and Fernandez, 1986). At the time of their discovery the similarity between megachannels and mitochondria1 VDAC prompted the speculation that
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the megachannels recorded with the patch-clamp technique were actually ‘‘lost’’ channels that had originated from mitochondria and had somehow wandered over to the plasma membrane and had been incorporated into the sarcolemma. Localization to the plasma membrane and the sarcoplasmic reticulum of large-conductance CI channels has been confirmed using immunohistochemical methods (Babel et al., 1991). The properties of these channels have been described in detail elsewhere (Blatz, 1990) and are only briefly discussed here.
1. Ion Selectivity Similar to the fast and slow CI channels in skeletal muscle, muscle megachannels exhibit a C1 to K or Na permeability ratio of about 4:6 (Blatz and Magleby, 1983). A systematic analysis of the relative permeabilities has not been performed on muscle megachannels.
2. Voltage Dependence Megachannels exhibit a characteristic voltage-dependent kinetic activity. With no potential difference across the membrane, megachannels are predominantly in the open state. When the membrane potential is stepped from 0 mV to either a positive or negative value, the open probability of these channels decreases with a time constant of about 1 sec to extremely small values (Fig. 7). It is this odd voltage dependence that has led to questions about the physiological relevance of the megachannel, since, under normal physiological conditions, one would expect the channel to remain closed. 111. NON-TRANSMITTER-ACTIVATEDNEURONAL CI CHANNELS
The surface membranes of neurons contain a variety of Cl-selective ion channels. By far the most widely studied have been those channels activated by GABA (for review, see Barker et al., 1990). Non-transmitteractivated Cl-selective channels have been reported in only a few types of neurons such as tissue-cultured rat hippocampus (Franciolini and Nonner, 1987; Franciolini and Petris, 1988), spinal cord (Hughes et al., 1987),and acutely dissociated rat cerebral cortex (Blatz, 1991). A. Ion Selectivity
The most complete investigation of the permeability properties of neuronal CI-selective ion channels was performed on tissue-cultured rat hippocampus neurons (Franciolini and Nonner, 1987). In this study it was found
6 . C1 Channels in Skeletal Muscle
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that a variety of monovalent anions were permeable, as were monovalent cations such as K and Na. Given the relatively high permeability ratio for cation permeation through neuronal C1 channels it might be expected that ion currents carried by these permeant cations should be measured. This has not been the case. When currents are measured in the presence of asymmetric or symmetric permeant cations in the absence of permeant anions, no currents can be detected. This suggests that the permeation pathway of neuronal C1 channels is complex and may involve interactions between the channel pore and ions and between the ions themselves inside
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of the pore. Franciolini and Nonner (1987) proposed that cations binding to a site located within the membrane electrical field give rise to the measured cation permeability. When the cations leave the channel pore, they do so coupled to an anion, and therefore no net current would be measured. B. Single-Channel Kinetics
C1 channels with properties very similar to those of the fast C1 channels found in tissue-cultured skeletal muscle have been reported in acutely dissociated rat cerebral cortical neurons (Blatz, 1991). The ion selectivity, voltage dependence, and kinetic activity of these neuronal fast C1 channels are nearly identical to their muscle counterparts. The stability of the gating of neuronal fast C1 channels makes them ideal objects for the study of single-channel kinetics. When dwell-time analysis was performed on neuronal fast C1 channels, it was found that the unconditional distributions of open and closed interval durations could be best fit by sums of two and six exponential components, respectively, suggesting that, during normal activity, these channels readily enter at least two open kinetic states and at least six closed states. The various modes of gating behavior that are characteristic of muscle fast C1 channels (Blatz and Magleby, 1986b) are also present in the neuronal channels (Blatz, 1991). C. Block by Quaternaty Ammonium Ions
Quaternary ammonium ions (QAs) have been used as probes of ion channels selective for K for many years (for review, see Stanfield, 1983). Even in light of the well-known nonselectivity of QA among cation channels, it is often reported that, since a particular process is reduced by QAs, then that process must depend on K channels. It has been learned that some C1 channels are also blocked by QAs (Lukas and Moczydlowski, 1990; Sanchez and Blatz, 1992), making reliance on QA block even more suspect. The QA used most commonly in electrophysiology is tetraethylammonium-ion (TEA). This compound blocks many K channels in the microto millimolar range (Stanfield, 1983). In many tissues, the TEA binding site is thought to be located inside the channel pores, within the electrical field of the membrane. Extracellularly applied TEA (TEA,) blocks neuronal fast C1 channels in a similar fashion (Sanchez and Blatz, 1992). Figure 8 shows the reduction of fast C1 channel currents recorded at
6. C1 Channels in Skeletal Muscle
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-40 mV in the presence of 0, 5 , and 10 mM TEA,. TEA block appears as a reduction in single-channel current suggesting that TEA binds and unbinds to its blocking site with kinetics that are much more rapid than can be resolved in these experiments (6 kHz). That the blocking kinetics must be much more rapid than is resolvable is suggested by the fact that the variance of the open channel current is not increased by concentrations of TEA, that reduce single-channel currents by 50% (Sanchez and Blatz, 1992). The dose-response relationship between the fractional current and [TEA,,] can be adequately fit assuming that two TEA molecules bind to the channel. Further analysis of the dose-response relationship revealed that it was impossible to differentiate between a blocking reaction involving two TEA molecules and a unimolecular reaction where a single TEA binding to the channel causes a reduction of current to 20% of the unblocked magnitude. The block of K channels by TEA is often dependent
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on membrane potential (Stanfield, 1938). This is also true for the TEA block of neuronal fast C1 channels as is shown in Fig. 9. Only the block by TEA, is voltage dependent under the conditions of these experiments suggesting that the sites for intracellular and extracellular TEA block are different. Analysis of the voltage dependence of TEA, block suggests that the blocking site is located within the electrical field of the membrane much as is imagined for K channel block. Increasing the hydrocarbon chains of symmetric QAs often leads to altered K channel blocking kinetics. Similarly, tetrapropyl (TPA) and tetrabutyl (TBA)-ammonium ions block neuronal fast C1 channels, at significantly lower concentrations than those required with TEA (Sanchez and Blatz, 1991). In the presence of TPA, fast C1 channel currents exhibit significantly reduced mean open interval durations while the open current level remains at the control value. Using the methods that were used to characterize the normal gating properties of C1 channels we are currently 10
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6 . C1 Channels in Skeletal Muscle
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attempting to determine the kinetic schemes underlying these blocking reactions.
N. SUMMARY The study of C1 channels is finally starting to approach the level of the study of the cation permeant channels. The advent of single-channel methods has led to the discovery of many different types of C1 channels in excitable tissues such as nerve and muscle. Several types of mammalian C1 channels have been cloned and their primary sequences determined. The way is now clear for the application of the techniques of molecular biology that have led to molecular models for cation channels to be applied to anion channels as well.
Acknowledgment Supported by NIH Grant GM-39731.
References Adrian. R. H.. and Bryant. S. H. (1974). On the repetitive discharge in myotonic muscle fibres. J . Physiol. (London) 240, 505-515. Babel. D.. Walter, G., Gotz. H., Thinnes. F. P.. Jugens. L.. Konig, U..and Hilschmenn. N. (1991). Studies on human porin. VI. production and characterization of eight monoclonal mouse antibodies against the human VDAC ”porin 31 HL” and their application for histotopological studies in human skeletal muscle. B i d . Chem. Hoppr-Sevler 372, 1027- 1034. Barker, J . L., Harrison, N. L.. and Owen, D. G . (1990). Pharmacology and physiology of CI- conductances activated by GABA in cultured mammalian central neurons. I n “Chloride Channels and Carriers in Nerve, Muscle. and Glial Cells” (F. J . AlvarezLeefmans and J. M. Russell, eds.), pp. 273-298. Plenum. New York. Barrett, J. N., Magleby, K. L., and Pallotta, B. S. (1982). Properties of single Ca-activated K channels in cultured rat muscle. J . Phvsiol. (London) 331, 21 1-230. Behrens. M. I., Oberhauser, A,, Bezanilla, F.. and Latorre. R. (1989). Batrachotoxinmodified sodium channels from squid optic nerve in planar bilayers. Ion conduction and gating properties. J . Gen. Physiol. 93, 23-41. Blatz, A. L. (1990). Chloride channels in skeletal muscle. I n “Chloride Channels and Carriers in Nerve. Muscle. and Glial Cells” (F. J . Alvarez-Leefmans and J. M. Russell, eds.). pp. 407-420. Plenum, New York. Blatz, A. L. (1991). Properties of single fast chloride channels from rat cerebral cortex neurons. J . Phvsiol. (London) 441, 1-21. Blatz. A. L., and Magleby, K. L. (1983). Voltage dependent CI- selective channels of large conductance in cultured rat muscle. Biophys. J. 43, 237-241. Blatz. A. L., and Magleby, K. L. (1984). Ion conductance and selectivity of single calciumactivated potassium channels in cultured rat muscle. J . Gen. Phvsiol. 84, 1-23. Blatz. A. L.. and Magleby, K. L. (1985). Single chloride-selective channels active at resting membrane potentials in cultured rat skeletal muscle. Biophys. J. 47, 119-123.
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Blatz, A. L.. and Magleby. K. L. (1986a). Correcting single channel data for missed events. Biophys. J . 49, 967-980. Blatz. A. L., and Magleby, K . L. (1986b). Quantitative description of three modes of activity of fast chloride channels from rat skeletal muscle. J . Physiol. (London) 378, 141-174. Blatz, A. L.. and Magleby, K. L. (1989). Adjacent interval analysis distinguishes among gating mechanisms for the fast chloride channel from rat skeletal muscle. J . Physiol. (London) 410, 561-585. Bretag. A. H. (1987). Muscle chloride channels. Physiol. Rev. 67, 618-724. Colombini, M. (1979). A candidate for the permeability pathway of the outer mitochondria1 membrane. Nature (London) 279, 643-645. Colquhoun, D., and Hawkes, A. G. (1983). The principles of stochastic interpretation of ion-channel mechanisms. In ”Single Channel Recording” (B. Sakmann and E. Neher, eds.). pp. 135-176. Plenum. New York. Colquhoun, D., and Sigworth, F. J. (1983). Fitting and statistical analysis of single-channel records. In “Single Channel Recording” (B. Sakmann and E. Neher, eds.). pp. 191-264. Plenum. New York. Franciolini. F., and Nonner, W. (1987). Anion and cation permeability of a chloride channel in rat hippocampal neurons. J . Gen. Physiol. 90, 453-478. Franciolini, F., and Petris, A. (1988). Single chloride channels in cultured rat neurons. Arch. Biochem. Biophys. 261, 97-102. Gray. P. T. A., Bevan. S., and Ritchie, J. M. (1984). High conductance anion-selective channels in rat cultured Schwann cells. Proc. R . Soc. London, Ser. B 221, 395-409. Hamill, 0. P.. Marty, A., Neher. E.. Sakmann. B., and Sigworth. F. J. (1981). Improved patch-clamp techniques for high-resolution current recording from cells and cell-free membrane patches. Pfuegers Arch. 391, 85-100. Hanrahan, J. W.. Alles, W. P., and Lewis, S. A. (1985). Single anion-selective channels in basolateral membrane of a mammalian tight epithelium. Proc. Natl. Acad. Sci. U . S . A . 82,779 1-7795. Hille. B. (1984). “Ionic Channels of Excitable Membranes.” Sinauer Assoc., Sunderland, MA. Hodgkin, A. L., and Horowicz, P. (1959). The influence of potassium and chloride ions on the membrane potential of single muscle fibres. J . Phyiol. (London) 148, 127-160. Hodgkin. A. L.. and Huxley, A. F. (1952). A quantitative description of membrane current and its application to conduction and excitation in nerve. J . Physiol. (London) 117, 500-544. Hughes, D., McBurney, R. N . , Smith, S. M . , and Zortec, R. (1987). Caesium ions activate chloride channels in rat cultured spinal cord neurones. J . Phyiol. (London)392,231-251. Hutter, 0. F., and Noble, D. (1960). The chloride conductance of frog skeletal muscle. J . Physiol. (London) 151, 89-102. Keller, B . U., Hartshorne, R. P., Talvenheimo. J. A., Catterall. W. A., and Montal, M. (1986). Sodium channels in planar lipid bilayers: channel gating kinetics of purified sodium channels modified by Batrachotoxin. J . Gen. Physiol. 88, 1-23. Lindau, M.. and Fernandez, J . M. (1986). A patch-clamp study of histamine-secreting cells. J . Gen. Physiol. 88, 349-368. Lukacs, G. L., and Moczydlowski, E. (1990). A chloride channel from lobster walking leg nerves. Characterization of single-channel properties in planar bilayers. J . Gen. Physiol. 96, 707-734. Magleby. K . L . , and Stevens, C. F. (1972). The effect of voltage on the time course of endplate currents. J. Physiol. (London) 223, 151-172.
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Magleby. K. L.. and Weiss, D. S. (1990). Estimating kinetic parameters for single channels with simulation. A general method that resolves the missed event problem and accounts for noise. Biophys. J . 58, 141 1-1426. Palade, P. T., and Barchi, R. L. (1977). Characteristics of the chloride conductance in muscle fibers of the rat diaphragm. J . Gen. Physiol. 69, 325-342. Roux. B.. and Sauve, R. (1985). A general solution to the time interval omission problem applied to single channel analysis. Biophvs. J . 48, 149-158. Sanchez. D. Y., and Blatz, A. L. (1991). Tetraethylammonium and related quaternary ammonium ions block chloride channels in cerebral cortical neurons. Soc. Neurosci. Abstr. 17, 1521 (abstr.). Sanchez, D. Y ., and Blatz, A. L. (1992). Voltage-dependent block of fast chloride channels from rat cortical neurons by external tetraethylammonium ion. J . Gen. Physiol. 100, 217-23 I . Schneider. G. T., Cook, D. I . . Gage. P. W.. and Young. J . A. (1985). Voltage sensitive, high conductance chloride channels in the luminal membrane of cultured pulmonary alveolar (type 11) cells. Pfluegers Arch. 404, 354-377. Schwarze, W., and Kolb. H. A. (1984). Voltage-dependent kinetics of an anionic channel of large unit conductance in macrophages and myotube membranes. PJluegers Arch. 402, 281-291. Stanfield. P. R. ( 1983).Tetraethylammonium ions and the potassium permeability of excitable cells. Rev. Physiol. Biochern. Pharrnacol. 97, 1-67. Weiss. D. S. (1988). Membrane potential modulates the activation of GABA-gated channels. J . Neurophvsiol. 59, 5 14-527. Weiss. D. S.. and Magleby, K . L. (1990). Voltage dependence and stability of the gating kinetics of the fast chloride channel from rat skeletal muscle. J . Plzysiol. (London)426, 145-176. Wilson. D. L., and Brown, A. M. (1985). Effect of limited interval resolution on single channel measurements with application to calcium channels. IEEE Trans. Biorned. Eng. 32, 786-797.
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CHAPTER 7
The CFTR Chloride Channel Michael J. Welsh, Matthew P. Anderson, Devra P. Rich, Herbert A. Berger, and David N. Sheppard Howard Hughes Medical Institute, Departments of Internal Medicine and Physiology and Biophysics, University of Iowa College of Medicine, Iowa City, Iowa 52242
I . Topology and Localization of CFTR 11. Localization of CFTR 111. Biophysical Properties of the CFTR C1- Channel
IV. Phosphorylation-Dependent Regulation of CFTR V. Nucleotide-Dependent Regulation of CFTR CI- Channels VI. Conclusion References
Cystic fibrosis transmembrane conductance regulator (CFTR) is a regulated CI- channel located in the apical membrane of several CI- secretory epithelia. Mutations in the gene encoding CFTR cause cystic fibrosis (CF) (Boat et ul., 1989). CFTR was discovered and its primary structure was identified by positional cloning (Rommens et al., 1989; Riordan et al., 1989; Kerem et a / . , 1989). Amino acid sequence analysis and comparison with other proteins suggested that CFTR consists of five domains (Riordan et a / . , 1989) (Fig. 1). Beginning at the amino terminus, there is a putative membrane-spanning domain (MSDl), composed of six hydrophobic sequences predicted to cross the membrane as a-helices. MSDl is followed by a nucleotide-binding domain (NBDl) in which there is sequence similarity with nucleotide binding domains from a number of other proteins. Then there is the R domain, which contains multiple phosphorylation sites for CAMP-dependent protein kinase (PKA) and protein kinase C (PKC). After the R domain, the protein reenters the membrane with a second membrane-spanning domain (MSD2)composed of six putative membraneCitrrriit T o p k s in Mrmbrcines, Volume 42 Copyright 0 1994 by Academic Press. Inc. All rights of reproduction in any form reserved.
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FIGURE 1 Model showing the proposed domain structure of CFTR. MSD refers to the membrane-spanning domains, NBD refers to the nucleotide-binding domains. and PKA refers to CAMP-dependent protein kinase. The membrane is represented by the shaded area. Some amino acids are indicated by residue number.
spanning sequences, followed by a second nucleotide binding domain (NBD2). Sequence similarity in the NBDs and the topology of CFTR (with the exception of the R domain) suggest that CFTR belongs to a family of proteins called the traffic ATPases (Ames et al., 1990) or the ATP binding cassette (ABC) transporters (Hyde et al., 1990). Most members of this family are ATP-dependent transporters, including periplasmic permeases in prokaryotes and the multidrug-resistant P-glycoprotein (MDR) which is responsible for chemotherapeutic drug resistance in eukaryotes. The similarity of CFTR to other members of this family suggested that CFTR might be an active transporter. However, studies indicate that CFTR is a C1- channel, regulated by CAMP-dependent phosphorylation and by intracellular ATP. The cytoplasmic NBDs and R domain distinguish CFTR from the structure of previously described voltage- and ligand-gated ion channels. Thus, CFTR may represent the first identified member of a new family of ion channels. The observation that expression of MDR is associated with volume-regulated CI- channels (Valverde et al., 1992; Gill et al., 1992) indicates that MDR may also be a CI- channel and suggests that other members of this family may also be ion channels. The conclusion that CFTR forms a CI- channel does not exclude the possibility that CFTR has additional, as yet undiscovered, functions (for example, see Egan el al., 1992; Boucher et al., 1986; Bradbury et al., 1992; Cheng et al., 1989; Tsui and Buchwald, 1991). Perhaps several members of the ABC transporter family will have more than one function.
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I. TOPOLOGY AND LOCALIZATION OF CFTR
The general topology of CFTR shown in Fig. 1 is not known with certainty, but the location of several sites with reference to the plasma membrane has been assessed (Denning et al., 1992a). The amino-terminus is likely to be intracellular because of the lack of a signal sequence (Riordan et al., 1989). The first predicted extracellular loop is likely to be extracellular because it is recognized by antibodies directed to that epitope in nonpermeabilized cells (Denning et al., 1992a,b) and because mutation of an arginine in that loop (R117) to histidine causes the channel to become dependent on extracellular pH (Sheppard et a[., 1993). NBDl and the R domain are likely to be intracellular because they are regulated by kinases and nucleotides applied to the cytosolic surface of excised, insideout membrane patches (see below) and because an antibody directed against the R domain only stains perrneabilized cells (Denning et al., 1992a). The fourth predicted extracellular loop is extracellular, because it contains sites that are glycosylated (Cheng et al., 1990; Gregory et af., 1991). NBD2 is intracellular because it interacts with intracellular nucleotides (see below). The carboxy-terminus is likely to be intracellular because it is recognized by antibodies only after cells have been permeabilized (Denning et al., 1992a). Although these observations support the model shown in Fig. 1, it is interesting that other members of the ABC transporter family contain fewer than 12 membrane-spanning sequences: MDR appears to have 6 membrane-spanning sequences in MSD I and 4 membrane-spanning sequences in MSD2 (Zhang and Ling, 1991; Skach et al., 1993). Additional studies are required to define the topology of CFTR with more precision.
11. LOCALIZATION OF CFTR
A number of antibodies have been used to immunolocalize CFTR. CFTR has been localized to the apical region of several epithelia, including small pancreatic ducts, intestinal epithelia, and several CI--secreting epithelial cell lines (Marino et al., 1991; Cohn et a / . , 1991; Crawford et a / . , 1991; Denning et ul., 1992a,b; Engelhardt and Wilson, 1992; Kartner et al., 1992; Trezise and Buchwald, 1991; Trezise et a/., 1992.1993). Evidence that CFTR is located within, rather than near, the apical membrane came from two types of studies. One set of studies showed that an antibody directed against an extracellular epitope labeled the apical membrane of unpermeabilized intestinal epithelial cell lines and primary cultures of airway epithelial cells (Denning et a / . , 1992a.b). Another study showed
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that CFTR could be labeled with biotin from the extracellular surface (Prince et uf., 1993).CFTR has also been localized by in sifir hybridization to several epithelia involved in CF (Trezise and Buchwald, 1991; Trezise et a!., 1992,1993; Engelhardt and Wilson, 1992). The conclusion that CFTR is a regulated CI- channel and the observation that it is located in the apical membrane place it in a location where its activation by PKA-dependent phosphorylation would directly mediate CIexit from the cell during transepithelial C1- secretion. Thus, it is possible to explain, at least at a superficial level, the observation that mutations in the gene for CFTR produce C1- impermeable epithelia in CF. But, it is also possible that CFTR is located beneath the apical membrane and functions on intracellular membranes (Barasch et al., 1991; Lukacs et al., 1992; Bradbury et al., 1992). 111. BIOPHYSICAL PROPERTIES OF THE CFTR CI- CHANNEL
CFTR cDNA has now been expressed in a variety of cell types by a number of different laboratories. In the first functional studies, CFTR cDNA was expressed in primary cultures of CF airway epithelial cells (Rich ei al., 1990) and in a CF pancreatic epithelial cell line (Drumm et al., 1990). Expression of wild-type CFTR in these cells corrected the defect in CAMP-regulated C1- permeability. Since then CFTR has been expressed in a number of cells that do not normally contain PKA-regulated CI- channels and express little or no endogenous CFTR. CFTR has been expressed in both mammalian and nonmammalian cells, including NIH 3T3 fibroblasts (Anderson e f al., 1991b,c; Berger e f d.,1991), Chinese hamster ovary cells (Anderson et al., 1991b; Tabcharani et al., 1991; Lukics et al., 1992),airway epithelial cells (Egan et al., 1992; Johnson et al., 1992), HeLa cells (Anderson et al., 1991b), mouse L cells (Rommens et ul., 1991; Dalemans er al., 1992), Vero cells (Dalemans et al., 1991), lymphocytes (Krauss er al., 1992), St9 insect cell line (Kartner et al., 1991; Bear et al., 1992), and Xenopus oocytes (Bear et ul., 1991; Drumm et al., 1991; Cunningham et al., 1992). In each case, expression of CFTR generated a unique C1current. The whole-cell properties of recombinant CFTR include a linear current-voltage (I- V ) relationship and minimal time-dependent voltage effects. The channels are selective for C1- over Na' and, in most reported cases, show an anion selectivity sequence of Br- > C1- > I-. Work from Hanrahan and co-workers suggests that I- binds to and blocks the channel
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reducing its permeability (Tabcharani et al., 1992). In any case, the anion selectivity sequence is a distinguishing feature of CFTR CI- currents, because it differs from the reported anion selectivity of some, but not all, other epithelial and nonepithelial CI- channels ( Frizzell and Halm, 1990; Anderson et al., 1992). The biophysical properties of recombinant CFTR CI- channels are the same as those of endogenous CFTR C1- channels. Under baseline conditions, there is little, if any, C1- current in cells endogenously expressing CFTR. But following addition of CAMP agonists, there is a dramatic increase in CI- current in both whole-cell patch-clamp studies in individual epithelial cells (Tabcharani et al., 1990; Cliff and Frizzell, 1990; Anderson and Welsh, 1991; Bear and Reyes, 1992; Haws et a/., 1992; Wagner et a / . , 1992) and studies of the apical membrane of C1- secretory epithelia (Anderson and Welsh, 1991). C1- channel activation does not occur in response to an increase in intracellular Ca’+. The CFTR CI- channel has also been studied at the single-channel level using the cell-attached and excised patch-clamp techniques. Figure 2A shows an example of single-channel traces from a CFTR C1- channel in an excised, inside-out membrane patch; Fig. 2B shows the corresponding I - V relationship. The channel has a small conductance (approximately 6-10 pS, depending on the study conditions) and a linear I-V relationship and is selective for anions over cations. The anion selectivity is similar to that observed in whole-cell patch-clamp studies and in studies of the apical membrane. CFTR has also been purified from Sf9 cells, reconstituted into proteoliposomes, and fused with planar lipid bilayers in the presence of PKA and ATP (Bear et a / . , 1992). After fusion, low conductance CI--selective channels appeared which had a linear I-V relationship and showed no appreciable time-dependent voltage effects. These properties were the same as those observed in the native cell membrane and support the conclusion that CFTR is a CI- channel. Similar results, including regulation by PKA, have been obtained when membrane vesicles from cells expressing high levels of CFTR have been fused with bilayers (Tilly et al., 1992; Bear er al., 1992). The ability of purified CFTR to function in bilayers argues against the requirement for loosely associated factors for regulation or function of the channel. Studies of CFTR containing site-directed mutations indicate that the MSDs may contribute to the channel pore. CFTR contains six positively charged amino acids within the putative membrane-spanning sequences. These residues are conserved across species, suggesting conservation of function. Four of the basic residues were individually converted to acidic
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ef al.
A
100 mV 80 mV 60 mV 40 mV
-0.8.
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20 mV 0 mV
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FIGURE 2 Single-channel current activated by PKA and ATP in excised, inside-out patch. Traces in (A) were obtained from a 3T3 fibroblast stably expressing CFTR. Voltages are indicated on the right. I-V relationship is shown in (B). Pipette contained 140 mM CI-; the bath CI- concentration was 139 mM in (A) and as indicated in (B). Reproduced from Berger et al. (1991) by copyright permission of the American Society for Clinical Investigation.
residues and the CFTR variants were studied using the whole-cell patchclamp technique (Anderson et al., 1991~).Each of the mutant forms of CFTR generated C1- channel currents. Many properties of these channels were unchanged by the mutations: in each mutant, PKA-dependent channel regulation was intact, selectivity for C1- over Na' was unaltered, and no time-dependent voltage effects were introduced. Thus the mutations did not cause a general disruption of channel structure. Yet two mutations,
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K95D and K335E,' each altered anion selectivity. With both mutations, the permeability sequence was converted from Br- > CI- > 1- to I- > Br- > C1-. The two mutations were not, however, equivalent: K335E altered the conductivity sequence more dramatically than did K95D. Mutation of two other basic residues, R347E and R1030E, did not change the selectivity sequence. It is interesting that, in the topological model of CFTR (Fig. I ) , both K95 and K335 are predicted to lie toward the outer portion of the membrane-spanning sequence, whereas R347 and R1030 are predicted to lie toward the inner half of the channel. Mutation of other amino acids located in MSDl can also change the conductive properties of CFTR. Three CF-associated mutations (R117H, R334W, and R347P) replace positively charged amino acids with neutral residues. Each variant retains normal regulation by PKA and ATP (Sheppard et ul., 1993). Moreover, each variant was selective for C1- over Na', each had a normal anion-selectivity sequence, there were no timedependent voltage effects, and the I-V relationships were linear. Nevertheless, the whole-cell currents were quantitatively reduced as compared to wild-type CFTR. The reduction in current resulted from decreases in both single-channel conductance and open-channel probability. Under the conditions of the study, wild-type CFTR had a slope conductance of 7.8 pS, R117H had aconductance of6.76 pS, and R347P had aconductance of 2.34 pS. Discrete channel openings could never be resolved with R334W, suggesting that its conductance was markedly reduced. The kinetics of the R117H variant were also altered, such that channel-open time appeared to be decreased and, as a result, open-state probability (Po)was reduced to less than one-third that of wild-type CFTR. The gating of the R347P channel appeared to be like that of the wild type. The finding that three different mutations (R334W, R347P. and K335E) altered specific properties of the conduction mechanism suggests that the putative sixth membrane-spanning sequence (M6) contributes to the pore of the CFTR CI- channel. The observations that mutations in M1 (K95D)and at the external surface of M2 (R117H) alter specific pore properties suggest that those sequences may also contribute to the formation of the channel pore. However, these data alone are insufficient to specifically identify the pore and additional studies will be required.
'
Mutants are named to include the amino acid residue number preceded by the wildtype amino acid, and followed by the amino acid to which the residue was changed, using the single-letter amino acid code. Thus K95D means that lysine residue 95 was changed to aspartate.
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Because, as we describe below, the NBDs regulate the opening and closing of the CFTR C1- channel, it is interesting to speculate that they might also contribute to formation of the channel pore (Arispe et al., 1992). That suggestion is supported by the work of Ames and co-workers (Baichwal et al., 1993; Shyamala et al., 1991) on the histidine transport system, another member of the ABC transporter family. HisP, which is analogous to the NBDs of CFTR, interacts with HisQ and HisM, two membrane proteins that are analogous to the MSDs of CFTR. Both genetic and biochemical studies suggest that HisP may span the bilayer. It is possible that such an interaction between analogous domains in CFTR may provide a mechanism for coupling the activity of the NBDs with ion flow.
N. PHOSPHORYLATION-DEPENDENT REGULATION OF CFTR CFTR is regulated by phosphorylation of the R domain. First, addition of cAMP agonists increases the apical membrane C1- permeability of normal, but not CF, epithelia (Knowles et al., 1983; Widdicombe et a l . , 1985), and addition of cAMP agonists activates CFTR C1- channels in heterologous cells expressing recombinant CFTR (see above). Second, addition of the catalytic subunit of PKA to the intracellular surface of excised, inside-out membrane patches activates CFTR CI- channels (Tabcharani et al., 1991; Berger et al., 1991). Third, phosphorylation of CFTR was increased in uiuo by addition of cAMP agonists to cells incubated with 32Piand in uitro by addition of PKA plus [y- 32P]ATP(Cheng e t u l . , 1991: Picciotto etal., 1992).Fourth, mutationofthe phosphorylation sites within the R domain alters channel regulation (see below). In addition to regulation by PKA, PKC can also phosphorylate and activate CFTR C1- channels (Tabcharani et al., 1991; Berger et al., 1993; Picciotto et al., 1992). However, the multifunctional Ca2+/calmodulindependent protein kinase failed to either activate or phosphorylate CFTR Cl- channels, suggesting that this enzyme has no direct effect on CFTR (Berger et al., 1993). Cyclic GMP-dependent protein kinase (cGK), purified from bovine lung, phosphorylated CFTR in uitro, but failed to activate CFTR C1- channels (Berger et al., 1993). These results suggest that, if cCK phosphorylates CFTR in uiuo, it does so at sites not involved in CFTR CI- channel activation. There is, however, some controversy about the effect of cGK and cGMP. Cyclic GMP failed to increase apical membrane CI- permeability in human airway epithelia in one study (Berger et al., 1993), but another study suggested that in T84 cells, cGK could acti-
7. CFTR Chloride Channel
vate CFTR (Lin et al., 1992). A third study suggested there was no role for cGK in regulation of CI- secretion in T84 cells (Forte et al., 1992). Additional studies may be required to evaluate the role of cGK. Stimulation of C1- secretion is reversible: the rate of secretion returns to basal values once the agonist is removed, and readdition of the agonist restimulates CI- secretion. This result indicates that phosphorylation of CFTR is reversible. CFTR that has been activated by PKA-dependent phosphorylation is dephosphorylated and inactivated by protein phosphatase 2A (PP2A) (Berger et al., 1993). The effect of PP2A was blocked by the phosphatase inhibitor calyculin A. Neither protein phosphatase 1 nor protein phosphatase 2B inactivated or dephosphorylated the channel. One study suggested that alkaline phosphatase might inactivate PKAphosphorylated CFTR C1- channels (Tabcharani et al., 1991). However, another study suggested that such inactivation might result from a phosphatase-dependent reduction in the ATP concentration of the bathing solution without dephosphorylating the channel (Berger et al., 1993). However, it remains possible that different isoforms of alkaline phosphatase might regulate CFTR. Although PP2A can dephosphorylate CFTR in vitro, it is not clear whether PP2A is the predominant phosphatase that is responsible for regulation of CFTR in viuo. Future studies may be required to identify and characterize epithelial-specific phosphatases. The R domain contains a number of potential phosphorylation sites for PKA (Riordan ef d., 1989). PKA favors t h e consensus phosphorylation sequence R-R/K-X-S*/T* (where the phosphoacceptor site is indicated by an asterisk and X indicates any amino acid). There are 10 “classic” PKA consensus sequences within CFTR: eight serines plus one threonine within the R domain and one serine just prior to NBDl. To identify the specific sites of phosphorylation, each of the 10 potential PKA phosphorylation sites was mutated individually to alanine. Each of the mutant CFTRs was phosphorylated in vitro and digested with trypsin, and the phosphopeptides were separated by two-dimensional electrophoresis (Cheng et nl., 1991). Each phosphopeptide was assigned to a specific serine by comparison of the wild-type and mutant fingerprints. Of the 10 potential phosphorylation sites, 7 were identified as phosphoacceptors in vifro and all were located within the R domain. Neither the threonine located within the R domain (T788) nor the serine located outside the R domain (S422) were phosphorylated in vitro by PKA. Of the 8 remaining potential phosphorylation sites, only 4 appeared to be phosphoacceptors in vivo: upon stimulation with CAMP, serines 660, 737, 795, and 813 were phosphorylated. All are located in the R domain. In the T84 intestinal epithelial cell
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line, an additional serine within the R domain (S700)was reported to be phosphorylated in uivo after stimulation by cAMP agonists (Picciotto et al., 1992). To investigate the functional consequences of phosphorylation, each of the mutant CFTRs (containing a serine to alanine mutation at one of the PKA phosphorylation sites) was expressed in heterologous cells and the response to cAMP agonists was assessed. Mutation of any single serine did not prevent cAMP from opening CFTR C1- channels, as assessed (SPQ)-halide efflux assay by the 6-methoxy-(3’-sulfopropyl)-quinolinium (Cheng et al., 1991). Because mutation of any one serine to alanine did not prevent PKA-dependent activation of the mutant CFTR CI- channels, multiple serines were mutated simultaneously to alanine. When all four of the serines that are phosphorylated in uiuo were mutated to alanine, CFTR C1- channel activity was substantially reduced. However, studies suggest that CFTR can still respond to cAMP agonists even when all four of the in viuo phosphorylation sites are mutated, albeit with a substantially lower level of channel activity. The functional consequences of deleting the R domain were also examined (Rich et al., 1991,1993).Expression of CFTR in which amino acids 708-835 were deleted (CFTRAR) generated C1- channels that had the same biophysical properties as wild-type CFTR with one important exception: they were open even without an increase in CAMP. Addition of cAMP agonists further activated CFTRAR C1- channels. These channels retain S660, one of the previously identified in viuo phosphorylation sites. Mutation of S660 to alanine in the combined mutant, CFTRARS660A, generated only constitutively active channels; addition of cAMP agonists caused no further increase in activity (Cheng et al., 1991). These data suggest that the R domain serves a regulatory role by keeping the channel closed. When the R domain is phosphorylated or when part of it is deleted, the channel opens. How could phosphorylation of the R domain open the channel? Phosphorylation might cause a conformational change in the R domain. Alternatively, phosphorylation-induced changes in charge might produce electrostatic forces that alter the interaction between the R domain and another part of the protein. This latter suggestion is supported by observations that mutation of the PKA consensus serines to negatively charged amino acids (such as aspartate) generate a channel that is open even without an increase in CAMP. It is interesting that regulation of CFTR by phosphorylation is so complex. It appears that phosphorylation is degenerate, in that phosphorylation occurs at multiple serines and phosphorylation of any combination of serines is sufficient to activate the channel. What is the reason for this complexity? It is possible that phosphorylation of multiple sites could
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provide a backup mechanism to ensure that phosphorylation activates the channel. Alternatively, it could slow the rate of complete dephosphorylation and thereby delay closing after removal of kinase. Finally, it is possible that graded levels of phosphorylation might produce graded levels of CFTR CI- channel activity. V. NUCLEOTIDE-DEPENDENT REGULATION OF CFTR CI- CHANNELS
As indicated above, CFTR contains NBDs that have amino acid sequence similarity with members of the ABC transporter family (Riordan et al., 1989; Ames et a/., 1990; Hyde et al., 1990). In most members of this family, the NBDs appear to be the site of ATP hydrolysis; the energy released during ATP hydrolysis is used to actively transport substrate across the cell membrane. Because CFTR functions as a C1- channel, rather than a C1- pump, the hypothesis that ATP might regulate the CFTR Cl- channel was tested (Anderson et al., 1991a). In excised, inside-out patches of membrane from cells expressing recombinant CFTR, CFTR C1- channels were activated by addition of PKA and ATP. However, once the ATP was removed, current returned to basal values (Fig. 3). Readdition of ATP alone reactivated the channels. The results indicate that ATP regulates the channel, but only when it has first been phosphorylated by PKA. A series of studies showed that PKA-dependent phosphorylation is relatively irreversible in those excised, inside-out membrane patches. The data also suggest that the effect of ATP does not occur through reversible phosphorylation of the CFTR CI- channel. Additional studies showed that as the concentration of Mg-ATP increased, the openstate probability (Po) of the phosphorylated channels increased. But the data appeared complex; they could not be fit by simple kinetic models, suggesting that there may be more than one site at which ATP interacts: those sites may be NBDl and NBD2. To determine whether ATP interacts directly with the NBDs in CFTR, the effect of Mg-ATP on CFTR containing site-directed mutations in the NBDs was examined (Anderson and Welsh, 1992). Each NBD contains a Walker A motif and a Walker B motif (Walker et al., 1982) which are conserved in the ABC transporter family and in many other proteins that where X is hydrolyze ATP. The Walker A motif is G-X-X-G-X-G-K, any amino acid. In the Walker A motif, lysine is thought to interact with either the CY or y phosphate of ATP. Mutation of the Walker A lysine in NBDl (K464A) or in NBD2 (K1250M) resulted in an altered relationship between (Mg-ATP concentration and channel activity. In both CFTR variants in which the Walker A lysine was mutated, Mg-ATP was less
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A
0.05 rnMMgATP
0.10 rnM MgATP
0.29 mM MgATP Time ( 5 ) 0.96 mM MgATP
-
1229 ms
FIGURE 3 Effect of ATP on CFTR CI- channel activity. (A) Data points are current at -40 mV from an excised, inside-out patch containing large numbers of channels. ATP ( 1 mM) and PKA (75 nM) were added during the times indicated. (B)Single-channel traces of a CFTR CI- channel of increasing concentrations of Mg-ATP applied to the cytosolic surface. From Anderson ef al., (1991a) and Anderson and Welsh (1992). with permission. 0 AAAS.
potent at stimulating channel activity. When the conserved aspartate in the Walker B motif (hhhhD, where h indicates a hydrophobic amino acid) of NBD2 was mutated (D1370M), the potency of Mg-ATP was also reduced. The Walker A lysine is followed by two hydroxyl amino acids in most members of the ABC transporter family. In NBDl of CFTR. the sequence is K-T-S. When the order of the two hydroxyls was switched to K-S-T, the Mg-ATP dose-response curve was shifted to the left. This result suggests that Mg-ATP is more potent at stimulating CFTR-TS465/ 6ST than wild-type CFTR. Biochemical studies have shown that nucleotides interact with a peptide from NBDl (Thomas et al., 1991,1992), a fusion protein that includes NBDl (Hartman et al., 1992),and with intact membrane-associated CFTR (Travis et al., 1993).These results plus the functional studies indicate that ATP interacts directly with CFTR and, more specifically, that it interacts with both NBDs. The data also suggest that an interaction of Mg-ATP with both NBDs is required for maximal channel activity. In some members of the ABC transporter family, the NBDs hydrolyze ATP. To assess this possibility for CFTR, the effect of nonhydrolyzable
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analogues was examined (Anderson ct d.,1991a; Carson and Welsh, 1993). Nonhydrolyzable ATP analogues, such as adenosine 5’4p.ymethyline) triphosphate (AMP-PCP) and adenosine 5‘-(/3,y-imido) trisphosphate (AMP-PNP), failed to activate CFTR CI- channels. Other nucleotides, such as ADP and AMP. also failed to activate CFTR. However, the requirement for nucleoside triphosphates was not highly specific. At a concentration of 1 mM, the nucleotide specificity sequence was ATP > AMP-CPP > GTP > ITP = UTP > CTP. This broad nucleotide specificity contrasts with the high specificity for ATP that is observed in a number of kinases, but is similar to that reported for other members of the ABC transporter family. Although AMP-PNP failed to activate CFTR, it also failed to inhibit the effect of ATP (Carson and Welsh, 1993). This result suggests that although AMP-PNP shares considerable structural similarity with ATP, it does not appreciably interact with the channel even when used at relatively high concentration ratios (0.3 mM ATP and 10 mM AMP-PNP). Mg’+ is a cofactor that is required in ATP hydrolysis reactions in other proteins. Mg’+ was also required for nucleotide-dependent regulation of CFTR. This result further suggests that ATP hydrolysis may be required to open CFTR CI- channels. Although studies in excised patches suggest that nonhydrolyzable analogues of ATP cannot activate the channel, studies of CFTR in sweat gland ducts and in T84 cells in which the basolateral membrane has been permeabilized suggest that nonhydrolyzable analogues can stimulate apical membrane CFTR C1- channels (Quinton and Reddy, 1992; Bell and Quinton, 1993). After permeabilizing the basolateral membrane, both cAMP and ATP were required to activate apical membrane CFTR C1channels. However, in the presence of cAMP plus low concentrations of ATP (0.1 mM), addition of either AMP-PMP or ATPyS stimulated secretion. Those data were interpreted to mean that nonhydrolyzable analogues may regulate CFTR via a nonhydrolytic interaction of ATP with the NBDs. At present it is not clear how to reconcile the observations in excised patches of membrane (AMP-PNP does not stimulate current in the presence of half-maximal concentrations of ATP) and in the intact cell. However, insights into the differences in these studies are likely to yield important new insights into the function and regulation of CFTR CIchannels. ADP is a product of ATP hydrolysis and is another abundant intracellular nucleotide whose concentration is influenced by the metabolic status of the cell. Although ADP alone did not stimulate channel activity, increasing concentrations of ADP progressively inhibited CFTR CI- channel current
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(Anderson pf al., 1991a). ADP proved to be a competitive antagonist of ATP, suggesting that ATP and ADP interact with the same site. Analogues of ADP also inhibited CFTR C1- channel activity: ADP > GDP = IDP > UDP > CDP > ADPpS. What is the physiologic relevance of CFTR regulation by Mg-ATP? One possibility is that nucleotide regulation provides a way of matching the rate of transepithelial C1- secretion with the availability of cellular ATP. Because apical membrane Cl- channels are a key site in the regulation of transepithelial CI- transport, they may represent an advantageous point at which to couple cellular ATP and ADP levels to transport. A decrease in cellular ATP (or increase ADP) would close apical C1- channels, thereby decreasing the rate of CI- secretion and consequently, the metabolic demand on the cells (Anderson et al., 1991a; Quinton and Reddy, 1992; Bell and Quinton, 1993).
VI. CONCLUSION
CFTR appears to be the first identified member of a novel class of C1channels. Regulation of CFTR is complex and involves both phosphorylation and an interaction with intracellular nucleotides. The combination of a molecular biologic approach (using site-directed mutagenesis and expression of CFTR in heterologous cells), a biochemical approach (using CFTR-specific antibodies), and an electrophysiologic approach (using the patch-clamp technique) is beginning to provide essential information about the structure and function of the various domains of this interesting channel.
Acknowledgments This work was supported in part by the Howard Hughes Medical Institute, The National Heart Lung and Blood Institute (HL42385, HL2985 I), and the Cystic Fibrosis Foundation. We also gratefully acknowledge our laboratory colleagues and our collaborators. Drs. Alan E. Smith. Richard J. Gregory, Seng H. Cheng, and their colleagues at Genzyme Corporation.
References Ames. G. F.-L., Mimura. C. S., and Shyamala, V. (1990). Bacterial periplasmic permeases belong to a family of transport proteins operating from Escherichia coli to human: Traffic ATPases. FEMS Microbiol. R e v . 75, 429-446. Anderson, M. P., and Welsh, M. J. (1991). Calcium and CAMP activate different chloride channels in the apical membrane of normal and cystic fibrosis epithelia. Proc. Natl. Acad. Sci. U . S . A . 88, 6003-6007. Anderson, M. P.. and Welsh, M. J. (1992). Regulation by ATP and ADP of CFTR chloride channels that contain mutant nucleotide-binding domains. Science 257, 1701-1704.
7. CFTR Chloride Channel Anderson. M. P.. Berger. H. A.. Rich, D. P.. Gregory. R. J.. Smith. A. E.. and Welsh M. J . (199la). Nucleoside triphosphates are required toopen the CFTRchloride channel. Cell (Coinbridge, Mass.) 67, 775-784. Anderson. M. P., Rich. D. P.. Gregory. R. J . . Smith, A. E.. and Welsh. M. J . 11991b). Generation of CAMP-activated chloride currents by expression of CFTR. Science 251, 679-682. Anderson. M. P.. Gregory R. J.. Thompson, S . . Souza, D. W.. Paul, S.. Mulligan. R. C.. Smith. A. E.. and Welsh. M. J . (1991~).Demonstration that CFTR is a chloride channel by alteration of its anion selectivity. Scienc,e 253, 202-205. Anderson. M. P.. Sheppard. D. N.. Berger. H. A,. and Welsh, M. J . (1992). Chloride channels in the apical membrane of normal and cystic fibrosis airway and intestinal epithelia. A m . J . Phvsiol. 263, LI-L14. Arispe. N., Rojas. E., Hartman. J . . Sorscher. E. J.. and Pollard H. B. (1992). Intrinsic anion channel activity of the recombinant first nucleotide-binding fold domain of the cystic fibrosis transmembrane regulator protein. Proc. Narl. Acad. Sci. U . S . A . 89, 1539- 1543. Baichwal, V . . Liu. D.. and Ames. G. F. (1993). The ATP-binding component o f a prokaryotic traffic ATPase is exposed to the periplasmic (external) surface. Proc. Natl. Acad. Sci. U . S . A . 90, 620-624. Barasch. J . . Kiss. B., Prince, A., Saiman. L.. Gruenert. D., and Al-Awqati. Q. (1991). Defective acidification of intracellular organelles in cystic fibrosis. Natirre (London) 352. 70-73. Bear. C. E.. and Reyes. E. F. 11992). CAMP-activated chloride conductance in the colonic . C251-C256. cell line, Caco-2. A m . J . P h ~ s i o l 262, Bear, C. E.. Duguay. F., Naismith. A. L., Kartner. N.. Hanrahan. J. W., and Riordan, J . R. (1991). CI- channel activity in Xenopus oocytes expressing the cystic fibrosis gene. J . Biol. Chem. 266, 19142-19145. Bear. C. E.. Li, C.. Kartner. N . . Bridges, R. J.. Jensen, T. J . . Ramjeesingh, M., and Riordan. J . R. (1992). Purification and functional reconstitution of the cystic fibrosis transmembrane conductance regulator (CFTR). Cell (Cambridge, Mass.) 68, 809-818. Bell. C. L., and Quinton. P. M. (1993). Regulation of CFTR C1- conductance in secretion by cellular energy levels. A m . J . Phvsiol. 264, C925-C931. Berger. H. A.. Anderson, M. P., Gregory, R. J . . Thompson, S., Howard. P. W.. Maurer, R. A . . Mulligan, R., Smith, A. E.. and Welsh, M. J . (1991). Identification and regulation of the cystic fibrosis transmembrane conductance regulator-generated chloride channel. J . Clin. Invest. 88, 1422-1431. Berger. H. A.. Travis. S. M., and Welsh, M. J . (1993). Regulation of the cystic fibrosis transmembrane conductance regulator CI- channel by specific protein kinases and protein phosphatases. J . Biol. Chem. 268, 2037-2047. Boat. T. F., Welsh. M. J.. and Beaudet, A. L . (1989). Cystic fibrosis. I n "The Metabolic Basis of Inherited Disease" (C. R. Scriver. A. L. Beaudet, W. S . Sly. and D. Valle, eds.). 6th ed.. Vol. 11. pp 2649-2680. McGraw-Hill. New York. Boucher, R. C.. Stutts. M. J., Knowles, M. R., Cantley. L.. and Gatzy. J . T. (1986). Na' transport in cystic fibrosis respiratory epithelia. Abnormal basal rate and response to adenylate cyclase activation. J . Clin. Invest. 78, 1245-1252. Bradbury. N. A.. Jilling, T., Berta, G . , Sorscher. E. J . . Bridges, R. J.. and Kirk. K. L. (1992). Regulation of plasma membrane recycling by CFTR. Science 256, 530-532. Carson. M. R., and Welsh, M . J . (1993). 5'-Adenylylimidodphosphate(AMP-PNP) does not activate CFTR chloride channels in cell-free patches of membrane. A m . J . Physiol. 265, L27-32.
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Cheng. P. W.. Boat. T. F.. Cranfill. K . , Yankaskas. J. R.. and Boucher. R. C. (1989). Increased sulfation of glycoconjugates by cultured nasal epithelial cells from patients with cystic fibrosis. J . Clin. fnuest. 84, 68-72. Cheng, S. H.. Gregory. R. J.. Marshall, J.. Paul, S.. Souza. D. W.. White. G . A.. O'Riordan. C. R.. and Smith. A. E. (1990). Defective intracellular transport and processing of CFTR is the molecular basis of most cystic fibrosis. Cell (Cumhridge. Mass.) 63, 827-834. Cheng. S . H.. Rich. D. P., Marshall. J.. Gregory. R. J.. Welsh. M. J.. and Smith. A. E. (1991). Phosphorylation of the R domain by CAMP-dependent protein kinase regulates the CFTR chloride channel. Cell (Cambridge. Mass.) 66, 1027- 1036. Cliff. W. H.. and Frizzell. R. A. (1990). Separate CI- conductances activated by CAMPand Ca?' in CI--secreting epithelial cells. Proc. Nail. Acud. Sci. U.S.A. 87, 4956-4960. Cohn. J. A.. Melhus. 0.. Page. L. J.. Dittrich. K. L.. and Vigna. S . R. (1991). CFTR: Development of high-affinity antibodies and localization in sweat gland. Biochrm. Biophvs. Res. Commrrn. 181, 36-43. Crawford. I.. Maloney, P. C.. Zeitlin. P. L., Guggino. W. B., Hyde. S. C.. Turley. H.. Gatter, K . C.. Harris. A.. and Higgins. C. F. (1991). lmmunocytochemical localization of the cystic fibrosis gene product CFTR. Proc. N u t / . Actrd. Sci. U.S.A. 88,9262-9266. Cunningham. S. A.. Worrell. R. T., Benos. D. J.. and Frizzell. R. A. (1992).CAMP-stimulated ion currents in Xenopirs oocytes expressing CFTR cRNA. Am. J . Physiol. 262, C783-C788. Dalemans. W.. Barbry. P.. Champigny. G . . Jallat. S.. Dott. K.. Dreyer. D.. Crystal. R. G . . Pavirani. A.. Lecocq, J. P.. and Lazdunski. M. (1991). Altered chloride ion channel kinetics associated with the A F508 cystic fibrosis mutation. Nufirre (,!.0/7d0n) 354, 526-528. Dalemans. W., Hinnrasky. J., Slos. P., Dreyer, D., Fuchey. C., Pavirani, A.. and Puchelle. E. (1992). lmmunocytochemical analysis reveals differences between the subcellular localization of normal and A Phe508 recombinant cystic fibrosis transmembrane conductance regulator. Exp. Cell. Res. 201, 235-240. Denning, G. M.. Ostedgaard. L. S.. Cheng, S . H., Smith. A. E.. and Welsh. M. J. (1992a). Localization of cystic fibrosis transmembrane conductance regulator in chloride secretory epithelia. J . Clin. Znuest. 89, 339-349. Denning. G . M., Ostedgaard, L. S . , and Welsh, M. J. (1992b). Abnormal localization of cystic fibrosis transmembrane conductance regulator in primary cultures of cystic fibrosis airway epithelia. J . Cell. B i d . 118, 551-559. Drumm, M. L.. Pope, H. A., Cliff, W. H., Rommens. J . M.. Marvin, S . A.. and Tsui. L.-C., Collins. F. S., Frizzell. R. A,, and Wilson. J. M. (1990). Correction of the cystic fibrosis defect in vitro by retrovirus-mediated gene transfer. Cell (Cambridge. Mass.) 62, 1227-1233. Drumm, M. L., Wilkinson, D. J.. Smit, L. S.. Worrell. R. T.. Strong. T. V.. Frizzell. R. A.. Dawson, D. C., and Collins, F. S. (1991). Chloride conductance expressed by A F508 and other mutant CFTRs in Xenoprts oocytes. Science 254, 1797-1799. Egan. M., Flotte, T., Afione, S.. Solow, R., Zeitlin, P. L.. Carter. B. J.. and Guggino. W. B. (1992). Defective regulation of outwardly rectifying CI- channels by protein kinase A corrected by insertion of CFTR. Nature (London)358, 581-584. Engelhardt, J. F.. and Wilson, J. M. (1992). Submucosal glands are the predominant site of CFTR expression in the human bronchus. Nut. Genet. 2, 240-248. Forte, L. R . . Thorne, P. K..Eber. S. L., Krause. W. J., Freeman, R. H.. Francis. S. H., and Corbin. J. D. (1992). Stimulation of intestinal CI- transport by heat-stable enterotoxin:
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Activation of CAMP-dependent protein kinase by cGMP. Au7. J . Physiol. 263, C607-Cb15. Frizzell. R. A.. and Halm. D. R. (1990). Chloride channels in epithelial cells. CIWI..Top. Memhr. T ~ n n s p37, . 247-282. Gill. D. R.. Hyde. S. C.. Higgins, C. F.. Valverde. M. A,. Mintenig. G. M.. and Sepulveda. F. V. (1992). Separation of drug transport and chloride channel functions of the human multidrug resistance P-glycoprotein. Cell (Cnmbridgc,Muss.)71, 23-32. Gregory. R. J.. Rich, D. P.. Cheng. S. H.. Souza. D. W.. Paul, S.. Manavalan. P., Anderson. M. P.. Welsh. M. J.. and Smith. A . E. (1991 ). Maturation and function of cystic fibrosis transmembrane conductance regulator variants bearing mutations in putative nucleotidebinding domains 1 and 2. Mol. Cdl. Biol. 11, 3886-3893. Hartrnan. J.. Huang. Z.. Rado. T. A.. Peng. S . . Jilling. T.. Muccio. D. D.. and Sorscher. E. J. ( 1992). Recombinant synthesis. purification. and nucleotide binding characteristics of the first nucleotide binding domain of the cystic fibrosis gene product. J . B i d . Chem. 267, 6455-6458. Haws. C.. Krouse. M. E.. Xia. Y.. Gruenert. D. C.. and Wine, J . J . (1992).CFTR channels in immortalized human airway cells. A m . J . Physiol. 263, L692-L707. Hyde. S. C.. Emsley. P.. Hartshorn. M. J.. Mimmack. M. M.. Gileadi. U..Pearce. S. R.. Gallagher, M. P.. Gill. D. R.. Hubbard. R. E.. and Higgins. C . F. (1990). Structural model of ATP-binding proteins associated with cystic fibrosis. multidrug resistance and bacterial transport. Notrrre (London)346, 362-365. Johnson. L. G.. Olsen. J. C.. Sarkadi. B.. Moore, K. L.. Swanstrom. R . . and Boucher. R . C. (1992). Efficiency of gene transfer for restoration of normal airway epithelial function in cystic fibrosis. Nrit. G m ~ t2,. 2 1-25, Kartner. N.. Hanrahan. J . W.. Jensen. T. J.. Naismith. A. L . . Sun, S . , Ackerley. C. A., Reyes. E. F.. Tsui. L.-C.. Romrnens. J. M.. Bear, C. E.. and Riordan. J. R. (1991). Expression of the cystic fibrosis gene in non-epithelial invertebrate cells produces a regulated anion conductance. Cell (Cambridge, Mass.) 64, 681-691. Kartner. N . , Augustinas, 0 . . Jensen. T. J., Naismith. A. L.. and Riordan. J. R. (1992). Mislocalization of AF508 CFTR in cystic fibrosis sweat gland. Nut. Genet. 1, 321-327. Kerem. B.-S.. Rommens. J. M.. Buchanan, J. A.. Markiewicz. D.. Cox. T. K.. Chakravarti, A,, Buchwald, M.. and Tsui. L.-C. (1989). Identification of the cystic fibrosis gene: Genetic analysis. Science 245, 1073-1080. Knowles. M.. Gatzy. J.. and Boucher, R. (1983). Relative ion permeability of normal and cystic fibrosis nasal epithelium. J . Clin. Invest. 71, 1410-1417. Krauss, R. D.. Bubien. J . K.. Drumm. M. L.. Zheng, T.. Peiper. S . C.. Collins. F. S . , Kirk. K. L., Frizzell. R. A., and Rado. T. A. (1992). Transfection of wild-type CFTR into cystic fibrosis lymphocytes restores chloride conductance at GI of the cell cycle. EMBO J . 11, 875-883. Lin. M., Nairn. A. C., and Guggino, S. E. (1992).cGMP-dependent protein kinase regulation of a chloride channel in T84 cells. Am. J . Physiol. 262, C1304-CI312. Lukacs. G. L.. Chang. X. B.. Kartner. N., Rotstein, 0. D.. Riordan. J. R.. and Grinstein. S. (1992). The cystic fibrosis transmembrane regulator is present and functional in endosornes. Role as a determinant of endosomal pH. J . B i d . Chem. 267, 1456814572. Marino. C. R., Matovcik. L. M.. Gorelick. F. S . . and Cohn. J. A . (1991). Localization of the cystic fibrosis transmembrane conductance regulator in pancreas. J . Clin. Invest. 88,712-716. Picciotto. M. R.. Cohn. J. A.. Bertuzzi. G.. Greengard. P.. and Nairn. A. C. (1992).Phosphor-
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ylation of cystic fibrosis transmembrane conductance regulator. J . B i d . Chem. 267, 12742-12752. Prince. L. S.. Tousson. A.. and Marchase. R. B. (1993). Cell surface labeling of CFTR in T84 cells. Am. J . Physiol. 264, C491-C498. Quinton. P. M.. and Reddy. M . M. (1992). Control of CFTR chloride conductance by ATP levels through non-hydrolytic binding. Nairrre (London)360, 79-81. Rich, D. P.. Anderson, M. P.. Gregory, R. J.. Cheng. S . H.. Paul. S . . Jefferson. D. M.. McCann. J. D.. Klinger. K. W.. Smith. A. E.. and Welsh. M. J. (1990). Expression of cystic fibrosis transmembrane conductance regulator corrects defective chloride channel regulation in cystic fibrosis airway epithelial cells. Natrrre (London)347, 358-363. Rich, D. P.. Gregory, R. J . . Anderson, M. P.. Manavalan. P.. Smith. A. E.. and Welsh. M. J. (1991). Effect of deleting the R domain on CFTR-generated chloride channels. Science 253, 205-207. Rich. D. P., Gregory, R. J . , Cheng. S. H.. Smith, A. E.. and Welsh. M. J. (1993). Effect of deletion mutations on the function of CFTR chloride channels. Recepr. Channels 1, 221-232. Riordan. J. R.. Rommens. J . M.. Kerem. B.-S.. Alon. N . . Rozmahel. R.. Grzelczak. Z.. Zielenski. J.. Lok. S . . Plavsic. N.. Chou. J.-L.. Drumm. M. L.. lannuzzi. M. C.. Collins. F. S . , and Tsui. L.-C. (1989). Identification of the cystic fibrosis gene: Cloning and characterization of complementary DNA. Science 245, 1066-1073. Rommens. J . M.. lannuzzi, M. C.. Kerem. B.-S.. Drumm, M. L.. Melmer. G.. Dean. M.. Rozmahel, R.. Cole, J. L.. Kennedy, D.. Hidaka, N.. Zsiga. M.. Buchwald. M.. Riordan. J. R.. Tsui. L.-C.. and Collins, F. S . (1989). Identification of the cystic fibrosis gene: Chromosome walking and jumping. Science 245, 1059-1065. Rommens, J. M., Dho. S . , Bear, C. E., Kartner. N . . Kennedy. D.. Riordan, J. R.. Tsui. L.-C., and Foskett. J. K. (1991). CAMP-inducible chloride conductance in mouse fibroblast lines stably expressing the human cystic fibrosis transmembrane conductance regulator. Proc. Nut/. Acad. Sci. U.S.A. 88,7500-7504. Sheppard D. N . , Rich, D. P., Ostedgaard, L. S. . Gregory. R. J.. Smith. A. E., and Welsh, M. J. (1993). Mutations in CFTR associated with mild disease from CI- channels with altered pore properties. Nature (London)362, 160-164. Shyamala, V.. Baichwal, V . . Beall, E., and Ames. G. F. (1991). Structure-function analysis of the histidine permease and comparison with cystic fibrosis mutations. J . B i d . Chem. 266, 18714- I87 19. Skach, W. R., Calayag, M. C.. and Lingappa, V. R. (1993). Evidence for an alternate model of human P-glycoprotein structure and biogenesis. J . Biol. Chem. 268, 6903-6908. Tabcharani, J. A., Low, W.. Elie. D., and Hanrahan. J. W. (1990). Low-conductancechloride channel activated by CAMP in the epithelial cell line T84. FEBS Lerr. 270, 157-164. Tabcharani, J. A., Chang, X.-B.. Riordan, J. R.. and Hanrahan, J. W. (1991). Phosphorylation-regulated C1- channel in CHO cetls stably expressing the cystic fibrosis gene. Nature (London) 352,628-63 I . Tabcharani, J. A., Chang. X.-B., Riordan. J. R., and Hanrahan. J. W. (1992). The cystic fibrosis transmembrane conductance regulator chloride channel. Iodide block and permeation. Biophys. J . 62, 1-4. Thomas, P. J., Shenbagamurthi, P., Ysern, X.. and Pedersen. P. L. (1991). Cystic fibrosis transmembrane conductance regulator: Nucleotide binding to a synthetic peptide. Science 251, 555-557. Thomas, P. J., Shenbagamurthi. P., Sondek. J., Hullihen, J. M.. and Pedersen. P. L. (1992). The cystic fibrosis transmembrane conductance regulator. Effects of the most common
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CHAMER 8
Chloride Conductances of Salt-Secreting Epithelial Cells Raymond A. Frizzell and Andrew P. Morris* Department of Physiology and Biophysics, University of Alabama at Birmingham, Birmingham. Alabama 35294; and *Departments of Physiology and Cell Biology, and Gastroenterology, University of Texas Health Science Center at Houston. Houston, Texas 77030
I. Introduction A. Cellular Mechanisms for CI Secretion B. Levels of Resolution 11. Secretagogue-Activated CI Conductances A. The CAMP-Activated CI Conductance: GAAMP B. The Ca-Activated C1 Conductance: G C C. Combined Effects of CAMP and Ca Ill. The Volume-Sensitive C1 Conductance: GZP’ A. Properties of the Whole-Cell Current B. Occurrence and Location C. Regulation D. Single-Channel Basis IV. The Outward Rectifier A. Ion Selectivity B. Blockers C. Regulation V. Summary References
1. INTRODUCTION
Chloride conductance pathways at the apical membranes of epithelial cells play a well-defined role in determining the rate of salt secretion across the epithelia that line the intestines, airways, and exocrine glands (Halm and Frizzell, 1990). Salt secretion is regulated on the secondsCurrent Topics in Membrones, Volume 42
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minutes time scale by a variety of endocrine substances, neurotransmitters, and immune cell products whose receptors lie predominantly at the plasma-facing, basolateral membranes. Secretion can be activated also by bacterial enterotoxins acting from the lumen, for example, those inducing intestinal secretion and diarrhea. There has been much interest in apical membrane receptors for regulatory substances released from immune cells (Madara et al., 1992; Castro et al., 1987). It is now generally accepted that the rate-determining step in transepithelial salt transport is the apical C1 conductance, Ga. The effects of secretory agonists are generally mediated by changes in the intracellular concentrations of two principal second-messenger pathways: cAMP and Ca. Thus, agonists such as VIP, prostaglandins, and isoproterenol activate adenylate cyclase-mediated cAMP accumulation. The resulting increase in protein kinase A (PKA) activity stimulates CI secretory mechanisms by phosphorylation. Another class of agonists includes acetylcholine, histamine, and bradykinin, which stimulate inositol phosphate production and a cellular Ca rise. In addition to these pathways, activation of protein kinase C (PKC) stimulates airway and intestinal secretion (Rao and DeJonge, 1990; Musch et al., 1990; Fondacaro and Henderson, 1985; Barthelson et al., 1987) and increases in cellular cGMP can activate Cl secretion in intestine (DeJonge and Rao, 1990). Their effects on the conductance pathways of secretory cells mimic the activation by cAMP and, as with CAMP-mediated agonists, are defective in cystic fibrosis (CF) intestine. The influence of different second-messenger pathways varies in different salt-secreting epithelial cells. For example, in the airways, CAMP-mediated agonists are primarily responsible for sustained stimulation of C1 secretion, whereas in sweat gland secretory coil, cholinergic agonists are predominately active. In other tissues, such as the intestines and several exocrine glands, both CAMP- and Ca-mediated secretory events are physiologically important. Moreover, the rate of secretion achieved when both classes of agonists act together is much greater than the sum of their individual activities, i.e., there is potentiation among agonists (see below). A. Cellular Mechanisms for CI Secretion
The cellular model for salt secretion that has dominated this field for 15 years (Frizzell et af.,1979) is shown in Fig. 1 . Chloride enters secretory
cells via a Na/K/CI co-transport process that is sensitive to inhibition by loop diuretics, e.g., furosemide and bumetanide. Sodium entering with C1 returns to the serosal interstitial space via the ouabain-sensitive Na/K pump. In tissues where net K secretion does not accompany C1 secretion,
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FIGURE 1 Model for CI secretion across secretory epithelia. The basolateral membranes contain the Na/K-ATPase, K channels, and the NalKIZCI co-transporter. The sensitivity of these transport processes to ouabain, K channel blockers, and furosemide, respectively, account for their inhibitory effects on CI secretion. At the apical membrane are shown two CI channels, one activated by CAMP-dependent phosphorylation. the other by a cellular Ca rise. Further details can be found in the text.
the K that enters via the pump is entirely recycled across the basolateral membrane through K conductance pathways. As a result of these processes, CI is accumulated within secretory cells to levels that exceed the thermodynamic activity of C1 in the external solutions. Thus, CI ions can exit across the apical membrane by diffusion in response to agonists that increase apical CI conductance or enhance the driving force for apical C1 exit. As discussed above, the conductance pathways in secretory cells are activated principally by increases in cellular CAMP or Ca. Together, the apical C1 and basolateral K conductance pathways carry a transepithelial current during secretory stimulation that causes the lumen to become electrically negative with respect to the serosal solution. This transepithelial voltage arises from a depolarization of the apical membrane potential produced by activation of the apical membrane C1 conductance and from the hyperpolarizing effect of the basolateral membrane K conductance on the basolateral membrane potential. This generates a lumen-negative transepithelial voltage that is proportional to the rate of C1 secretion, and this voltage provides the driving force for transepithelial N a secretion. Sodium traverses the paracellular pathways inasmuch as the driving force at the apical membrane favors Na entry rather than Na exit. As a result of these cellular transport mechanisms, salt accumulates in the lumen, providing an osmotic driving force for net water secretion. The secretory
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products of most tissues of this type are approximately isotonic to plasma. The activities of several of the transport mechanisms shown in Fig. I are subject to regulation by intracellular second messengers or cellular homeostatic mechanisms (Rao and DeJonge, 1990; DeJonge and Rao, 1990). However, the principal focus of this article is on the regulated Cl conductance pathways that contribute to salt secretion across epithelial cells. These pathways have received considerable attention in recent years because of their role in the etiology of cystic fibrosis (CF). CF affects the transport properties of virtually all salt-secreting epithelial cells (Quinton, 1990);a loss of apical membrane C1 permeability is a common phenotypic feature of this disease. This review has two primary goals. The first is to provide an update on the properties of C1 conductances in salt-secreting epithelial cells and to resolve, insofar as possible, their single-channel basis and mechanisms of regulation. A second goal is to consider the implications for cystic fibrosis research of the presence of different C1 conductances in these epithelia. 8. Levels of Resolution A variety of methods have been used to quantify epithelial C1 secretion and assess the properties of the regulated C1 conductances of secretory cells. Early 'measurements performed on intestinal epithelial sheets identified a transepithelial component of the short-circuit current (Isc) across the intestine that was equal to the net CI flux from serosa-to-mucosa (Field er al., 1968). Ion substitution experiments showed that C1 replacement abolished net C1 flow and the I,,, arguing that C1 was the actively transported species (Field et al., 1972).Stimulation of both current and transepithelial conductance by secretory agonists led to the concept of a secretory CI conductance. The dependence of transepithelial C1 transport on serosal Na and its inhibition by loop diuretics and ouabain implicated the basolatera1 transport mechanisms shown in Fig. 1 in providing for net C1 entry across the basolateral membranes and cellular C1 accumulation (Silva et ul., 1977; Heintze et al., 1983). Studies conducted in airway epithelial sheets and cultured intestinal cell monolayers provided confirmation for the basic transport features of this model (Welsh er al., 1982, 1983). Voltage and ion-sensing microelectrode studies provided additional support for the roles of these specific transport events in establishing the driving forces necessary for C1 secretion and implicated the secretory C1 conductance at the apical membrane as the primary regulated transport event. Secretagogue responses such as that illustrated in Fig. 2 were identified in canine tracheal apical membranes (Welsh et a / . , 1983). Stimulation by
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8. Salt Secretion in Epithelial Cells
-60
Rm KR.cm2
?i\;;-.., 1
,
0
0
1
2
Time (min) FIGURE 2 Time course of stimulation of CI secretion as reflected by changes in the CI secretory current &). the apical membrane voltage (VJ, and the apical and basolateral membrane resistances ( R , and Rb). Further discussion of these changes can be found in the text; data adapted from Welsh et d.(1983).
a CAMP-mediated agonist, in this case epinephrine, produces a timedependent increase in a short-circuit current (Zsc), reflecting the rate of C1 secretion, and a distinct pattern of changes in the apical membrane potential (V,) and the apical and basolateral membrane resistances ( R , and Rb). The initial event in stimulation of transepithelial current flow is a marked decrease in the electrical resistance of the apical membrane, which required the presence of CI in the bathing media. This increase in apical C1 conductance is the first and presumably rate-determining step in stimulation of transepithelial C1 transport. As a result of this marked increase in apical CI conductance, the electrical potential difference across the apical membrane, V,, approaches the equilibrium potential for CI across this barrier (-30 mV). With C1 at equilibrium, no further secretion would occur; however, a secondary change in basolateral membrane K conductance (shown by the delayed decrease in Rb) hyperpolarizes the voltages at both the basolateral and the apical membranes (electrical coupling between the opposing membranes being provided by current flow through the paracellular pathway), and this cellular hyperpolarization establishes the electrochemical driving force for apical C1 exit. The essential
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role of the basolateral membrane K conductance change is illustrated by the abolition of net CI secretion elicited by K channel blockers or by depolarization of the membrane potentials by elevated serosal solution K concentration (Smith and Frizzell, 1984). Importantly, ion substitution experiments conducted during microelectrode recordings showed unequivocally the locations of the C1 and K conductances at the apical and basolateral membranes, respectively. However, further resolution and characterization of the secretory C1 conductance by traditional methods, such as the use of ion channel blockers, did not provide much additional insight into the number or nature of these C1 conductance pathways due to the lack of sufficient specificity and the voltage dependency of several pharmacologic compounds in blocking C1 conductance pathways. The major limitations imposed by microelectrode studies, i.e., lack of control of driving forces and failure to isolate the individual conductance pathways, were overcome by the application of patch-clamp techniques to secretory epithelial cells (Frizzell et al., 1986; Welsh and Liedtke, 1986). Cell-attached, single-channel, and whole-cell current recordings have provided the opportunity to identify C1 channels activated by secretagogues that are known to perturb specific signal transduction pathways. Continued activity of these channels in excised membrane patches or after incorporation into planar lipid bilayers has allowed explicit characterization of their biophysical properties, including single-channel conductance, kinetics, voltage-dependence, ion selectivity, and blocker pharmacology. Identification of the single-channel events responsible for the secretory C1 currents evoked by different classes of agonists is still proceeding. However, the search has so far identified several of the players. It has emphasized also the importance of attempting to keep track of the biophysical fingerprints of these channels at all levels of resolution, from the identification of single-channel events to the measurement of transepithelial CI fluxes. 11. SECRETAGOCUE-ACTIVATED CI CONDUCTANCES
Transepithelial measurements of C1 secretion provided suggestive evidence for the presence of more than one apical membrane C1 conductance pathway. Different agonists produce secretory responses that differ in time course (sustained vs transient) (Dharmsathaphorn etaf., 1984). Those agonists that produce similar secretory responses are thought to perturb the same signaling and transport mechanisms because their responses are not additive. On the other hand, the responses to agonists that produce
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different patterns of secretory response are more than additive, they are synergistic. Thus, the combined presence of CAMP- and Ca-mediated secretory agonists (e.g., VIP plus carbachol) does not merely produce an additive secretory response, but shows potentiation, a phenomenon in which the secretion rate is greater than the sum of the individual agonist effects. Potentiation is due, in part, to the tendency for CAMP-mediated agonists to stimulate primarily the apical membrane C1 conductance, whereas Ca-dependent agonists act primarily on the basolateral membrane K conductance (see below, and Cartwright et af., 1985). Thus, their combined effects potentiate due to the activation of different transport components of the secretory pathway; however, the ability of each agonist to elicit secretion on its own also raised the possibility that Ca and cAMP activate different apical C1 conductances. The presence of distinct C1 conductances activated by cAMP and Ca has been demonstrated in airway and intestinal cells (Cliff and Frizzell, 1990; Anderson and Welsh, 1991) and in nonepithelial cells as well (McDonald et al., 1992). A. The CAMP-Activated CI Conductance: G c y P
A variety of agonists utilize increases in intracellular cAMP as the transducer for their secretory effects, and they include VIP, prostaglandins, P-adrenergic agonists, and adenosine. Stimulation via this mechanism usually elicits a sustained level of salt secretion, whereas the stimulation produced by Ca-dependent agonists is transient (see below).
1. Properties of the Macroscopic Whole-Cell Current a. Time and Voltage Dependence. The C1 conductance pathway activated by cAMP analogues, forskolin, or agonists that raise cellular cAMP displays distinct biophysical properties that distinguish it from other cellular CI conductances (Cliff and Frizzell, 1990). Figure 3A shows the C1 currents activated by cAMP during whole-cell voltage clamp. The CAMPactivated currents are time independent, showing no significant activation or inactivation at holding potentials of 2 100 mV (Cliff and Frizzell, 1990; Wagner et al., 1991; McDonald et al., 1992; Anderson and Welsh, 1991). The corresponding current-voltage relation, constructed from currents taken at any time following the initial capacitative current transient, is linear. The current magnitude and time course are independent of prepulse voltage history. This is an ohmic pathway, and the underlying singlechannel events are expected to conform to this behavior.
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-
L
7 +lo0 mV +80 +60 +40
-
+20
. -20 ' P
- *
B
T
0
4 0 -60 -80
3.5 nA/20pF
mV
-1.5 1 FIGURE 3 Properties of G;tMp. (A) CAMP-activated whole-cell currents in a T84 cell. Overlay of currents recorded during voltage pulses to *I00 rnV during steady-state stirnulation by 5 p M forskolin. (B) Instantaneous I-V relation for the currents shown in A.
6. Zon Selectivity. The halide selectivity determined during ion replacement under whole-cell patch-clamp conforms to Eiseman sequence 111 for the halide anions: Br > CI > I > F (Cliff and Frizzell, 1990;Anderson and Welsh, 1991). P,,/P, is 2.5 at standard physiologic concentrations of these anions. The low apparent iodide permeability is in part due to channel block by I, which apparently can be relieved at high I concentrations (Tabcharani et al., 1992). At high salt, the selectivity reverts to the Eiseman I sequence ( I > Br > CI > F), which is similar to that found in other epithelial anion conductance pathways (see below).
-
c . Blocker Sensiriuify. The blocker sensitivity of this conductance pathway has not yet been examined in great detail. Gray et al. (1990)
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showed block of the single channels corresponding to G,'PMP (see below) by 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB) during cellattached recording from human and rat pancreatic duct cells in primary culture. They found no effect of4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS) on the same channel. This conductance pathway can generally be distinguished from the other CI conductances by its lack of sensitivity to the disulfonic stilbenes (Anderson and Welsh, 1991). Both inward and outward currents through G,'pMP are unaffected by DIDS or DNDS at concentrations as high as 100 p M . Two nonsteroidal anti-inflammatory agents, niflumic acid and flufenamic acid, have been shown to inhibit CI secretion across cultured airway cell monolayers (Chao and Mochizuki, 1992)with IC,, values in the low micromolar range. Their effects on the single C1 channels corresponding to G,'pMP have not been examined. Reagents that block or open ATP-sensitive K channels are blocker of G:PMP (Sheppard and Welsh, 1992). Sulfonylureas inhibit whole-cell C1 currents stimulated by CAMP;the most potent was glibenclamide with an IC,, of 20 p M . Potassium channel openers also blocked G$'MP. The single-channel events opened by CAMP-dependent phosphorylation are ATP sensitive (see below) so that similar mechanisms may govern the interaction of the nucleotide binding domains of these channels with these compounds. Detailed single-channel studies will be required to assess whether their binding sites correspond with those for nucleotides (DeRoos et d., 1993).These agents appear to act as fast open channel blockers at the single-channel level and their apparent specificity for G;PMP suggests that they may be useful for the development of antidiarrheal drugs.
2. Single-Channel Basis of G;FMP The single-channel responsible for the CAMP-activated C1 conductance was first identified in cell-attached patches using primary cultures of pancreatic duct cells (Gray er ul., 1988).Similar channels have been observed to be activated by CAMPin a variety of systems in which the cystic fibrosis gene is expressed endogenously, or exogenously in both epithelial or nonepithelial cells (Tabcharani et ul., 1990,1991;Cliff et ul., 1992;Pollard et ul., 1991;Champigny et ul., 1990;Levesque et ul., 1992;Nagel er ul., 1992;Duszyk o r al., 1992). Despite the range of single-channel conductances observed in different expression systems (ca. 4- 14 pS), a consistent finding is this channel's linear I-V relation and its activation by CAMP. These small conductance CI channels share similarities in single-channel conductance, kinetics, and lack of sensitivity to blockade by the stilbene disulfonates and thus resemble the properties of the whole-cell currents (Cliff and Frizzell, 1990;Tabcharani et al., 1990).The anion selectivity
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of these channels also corresponds to that observed for the whole-cell current, in particular, the low permeability to iodide relative to C1 (Gray rt al., 1990; Berger et al., 1991). There is now little or no doubt that this small linear C1 channel is the cystic fibrosis transmembrane conductance regulator (CFTR). Evidence favoring this view is derived from three types of observations: (a) expression of CFTR cDNA in CF cells or cells that normally do not express CFTR results in the appearance of low-conductance C1 channel activity activated by CAMP and inhibited by NPPB (Rich et al., 1990; Drumm et al., 1990, 1991; Anderson et af., 1991b; Kartner et al., 1991; Bear et af., 1991; Cunningham et al., 1992), (b) introduction of mutations into CFTR alters its halide selectivity or the channel’s gating properties (Anderson et al., 1991c; Dalemans et al., 1991; Denning et al., 1992b), and, most convincing, (c) reconstitution of purified CFTR protein into planar lipid bilayers produces a channel with properties like those of the low conductance, linear I-V C1 channel in CFTR-expressing cells, and its activity in the bilayer requires phosphorylation by protein kinase A (Bear er al., 1992). In cell-attached patches, CFTR CI channels are activated by increases in cellular CAMP. However, the details of channel regulation have been further defined using excised inside-out membrane patches. CFTR CI channels can be activated by PKA and inactivated by protein phosphatase, indicating that reversible protein phosphorylation is required for channel opening (Tabcharani et al., 1991; Berger et af., 1993).Further studies have identified two distinct steps in this activation sequence which conform to the predicted presence, from structural modeling and homology, of CFTR domains for regulation by phosphorylation and for ATP binding and/or hydrolysis. The central portion of this molecule consists of a highly charged region of -250 amino acids that comprises the R (regulatory) domain. This region possesses several putative sites for phosphorylation by protein kinases (Riordan et al., 1989). Site-directed mutagenesis of four serines in the R domain has shown that their phosphorylation is crucial for regulated C1 transport. In uiuo phosphorylation studies have implicated these residues (S660, S737, S795, and S813) as sites of phosphorylation by protein kinase A (Rich et af., 1991; Cheng et af., 1991). However, studies suggest that other phosphorylation sites, perhaps sites that are not traditional consensus sequences for PKA-mediated phosphorylation, may also be important in CFTR activation ( J . W. Hanrahan, personal communication). Our knowledge of the extent of channel activity relative to the phosphorylation status of the protein is far from complete. The conceptual model upon which most studies are currently based involves a phosphorylation-induced conformational change in the R do-
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main that exposes a conduction pathway for transmembrane C1 flow. This is conceptually similar to the “ball and chain” model for regulation of K channel gating (Hoshi et ul., 1990). The idea that the R domain occludes the conduction pathway is supported by studies in which part of the R domain was removed by deletional mutation, producing a mutant channel with constitutive activity. Studies modeled after those on K channel regulation, which have employed synthetic peptides to mimic the channel gating process (Zagotta et al., 1990), will be difficult for CFTR because of the size and complexity of regulatory sites in the R domain. Subsequent to phosphorylation-induced CFTR channel activation, removal of PKA and ATP produces a cessation of channel activity which can be restored by adding back ATP alone (Anderson et al., 1991a). Thus, two steps appear to be involved in CFTR conduction: R domain phosphorylation by PKA + ATP, followed by ATP binding to one or both NBFs; the latter being necessary to maintain channel activity. These results provide evidence that ATP itself directly regulates CFTR gating, as for other ATP-dependent ion channels. These two regulatory steps fit well with the predicted structure of CFTR, involving separate regulatory and nucleotide binding domains. Many CFTR mutations involve the nucleotide binding domains, confirming the importance of ATP binding for the normal function of CFTR. There is also evidence that ATP binds to CFTR. Synthetic peptides and purified recombinant proteins corresponding to the first nucleotide binding domain bind ATP and ATP derivatives (Thomas et al., 1991; Hartman et af., 1992). These findings on ATP binding and channel gating appear comparable to those obtained from other transport ATPase family members, which bind and hydrolyze ATP to drive solute transport across the plasma membrane. However, the issue of ATP hydrolysis by CFTR, at least in the context of CI channel function, is not resolved at the present time. The initial studies of Anderson et al. (1991a) demonstrated that in contrast to ATP and other nucleotide triphosphates, nonhydrolyzable ATP analogues did not support CFTR C1 channel activity. Conflicting results have been obtained for the apical membrane C1 conductance of sweat duct and T84 cells. In epithelia where the basolateral membrane was permeabilized with a-toxin, Quinton and colleagues (Quinton and Reddy, 1992; Bell and Quinton, 1993) found that some nonhydrolyzable ATP analogues could keep the apical C1 conductance open. In excised membrane patches, Schultz et uf.(1993) found that the lack of CFTR channel activation by nonhydrolyzable ATP analogues could be explained by a failure of these compounds to interact with CFTR. Unlike ADP, these substances did not compete with ATP for channel activation, and, therefore, their inability to gate CFTR cannot be used to infer that CFTR
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hydrolyzes ATP. The results of the Quinton and colleagues are still difficult to reconcile with these findings. For example, they could maintain apical CI conductance with ATPyS, whereas this compound was not effective in the single-channel studies of CFTR. There are some potential alternate explanations for the studies in permeabilized epithelia or epithelial monolayers, however. The ATP concentration dependence of conductance activation occurs at very high ATP concentrations (in the millimolar range compared to a micromolar EC,, observed in the excised patch experiments). The possibility of displacement of bound or compartmentalized ATP by ATP analogues should be evaluated. Second, it is not certain that the conductance pathway opened by ATPyS, for example, is due to CFTR. Nucleotides activate alternate CI conductance pathways in other epithelia (Stutts er al., 1992). The results of recent studies show that ATP increases the open probability of CFTR CI channels as a simple Michaelis-Menten function of [ATPI in excised membrane patches (Venglarik et a/., 1994). The effect of ATP on Po was half-maximal at 24 pM ATP and Po reached a maximum value of 0.44 at saturating [ATP]. The relation of Po to ATP showed a Hill coefficient of unity, suggesting that there is no cooperativity among the two potential sites (NBFs) for ATP binding. The results of current fluctuation analysis of multiple single-channel currents yielded identical results and also provided the on and off rate coefficients for ATP association. These values agreed well with those derived from the single-channel analysis and were most consistent with a noncooperative three-state model for CFTR activation by ATP subsequent to phosphorylation. Accordingly, ATP binding to the channel places it in another closed conformational state, which can then open spontaneously. Thus, there are two ATP bound states: one open and one closed. The ATP bound state is not simply open, because Po would be 1 .0 at high [ATP], and it is less than half this value. This model of CFTR gating by ATP should serve as a basis to further define the CFTR channel effects of pharmacological modulators and of CFTR mutations. A rapid loss ur”channel activity after patch excision is sometimes a feature of this small conductance CI channel. This inactivation of channels in excised patches has been interpreted as suggesting that there are substances in the cell required for channel activity and that these factors are retained during whole-cell recordings, but are rapidly lost after patch excision (Kunzelmann et a/., 1991b; Krick ef al., 1991). It seems more likely that this “rundown” phenomenon represents a loss of channel activation by phosphorylation, which is likely to be mediated by the presence of membrane-associated phosphatase(s) in some cell types (Tabcharani et al., 1991; Berger et al., 1991).Following channel rundown, exposure
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of excised patches to the catalytic subunit of PKA and ATP restores channel activity to patches excised from CFTR-expressing CHO cells. 3. Occurrence This conductance pathway is found at the apical membranes of CAMP responsive secretory epithelia, including intestinal (Tabcharani et a/., 19901, airway (Gabriel et a/., 1993).pancreatic (Gray e t a / . , 1988),choroid plexus (Christensen et al., 19891, thyroid (Champigny et al., 1990), renal (Marunaka and Eaton, 19901, and epididymal (Pollard et a/., 1991) cells. Currents with these properties are present also in lymphocytes (Krauss et d., 1992) and cardiac cells (Levesque et a/., 1992; Nagel et a/., 1992) following activation by CAMP analogues. These currents, in both epithelial and nonepithelial cell types, correlate with the expression of the C F gene product, CFTR. The presence of a CAMP-activated Cl conductance at the apical membranes of other epithelia, including sweat gland reabsorptive duct (Cohn et u/.,1991; Kartner et a / . , 1992), pancreatic and biliary duct cells (Marino et a / . , 1991; Crawford et a/., 1991), is inferred from CFTR localization studies. Nevertheless, the single-channel currents themselves have not been monitored directly in all of these systems.
4. Cellular Location A variety of immunolocalization studies have demonstrated that CFTR is present at the apical membranes of secretory epithelial cells, corresponding to its role in CI secretion (Fig. I). CFTR has also been localized to the apical and basolateral membranes of sweat duct cells, with the densest staining at the apical border (Cohn et a/., 1991; Kartner et a/., 1992). Other studies have demonstrated that CFTR can be detected at the apical membranes of the T84 colonic cell line, using both antibody and protein-labeling immunoprecipitation methods (Denning et a / ., 1992a; Prince er a / . , 1993). Studies conducted with Brefeldin A (BFA), an inhibitor of the outward migration of integral membrane glycoproteins, confirm this correlation between apical CFTR location and the CAMP-activated CI conductance response (Morris et a/., 1993). BFA inhibits the CAMPactivated short-circuit current across HT-29 colon cell monolayers with a half-time of -10 hr. With a similar time course, BFA causes the loss of apical domain staining of CFTR, and the protein accumulates in intracellular vesicles, unable to target to the apical domain. BFA prevents the outward migration of glycoproteins along the protein secretory pathway and thus interferes with the apical targeting of CFTR. The loss of CAMPactivated apical CI conductance reflects the time course of CFTR retrieval from the apical membrane domain, and these results are in agreement
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Raymond A. Frizzell and Andrew P. Morris
with the time course of transport downregulation following inhibition of CFTR transcription (Trapnell et ul., 1991). Other evidence suggests that membrane-trafficking events, including both endocytosis and exocytosis, are regulated by cAMP in CFTRexpressing epithelia (Sorscher et al., 1992; Bradbury et al., 1992a,b). The exogenous expression of CFTR brings these membrane-trafficking events under regulation by CAMP, where no such regulation existed prior to CFTR expression (Bradbury et al., 1992a). Thus, CFTR confers CAMPdependent regulation on these membrane-trafficking events, and this raises the possibility that CFTR itself targets into the surface membrane during stimulation of C1 secretion. Accordingly, there may be two mechanisms for increasing the apical membrane C1 conductance of secretory epithelia in response to CAMP:(a) direct regulation, via phosophorylation, of membrane-resident CFTR and (b) an increase in the amount of CFTR in the membrane brought about by both a decrease in CFTR retrieval from. and an increase in CFTR insertion into, the apical membrane. Although the extent of C1 conductance stimulation generally correlates with the level of CFTR expression, there are exceptions to this paradigm. One of these occurs during cellular differentiation in colonic epithelial cells. Subclones of the HT-29 human colon cell lines exist in a variety of levels of differentiation. The parental cells are undifferentiated, pleuripotent cells that do not polarize to form apical and basolateral membranes, and no increase in C1 conductance is observed in response to elevated cellular cAMP (Morris et al., 1992). In contrast, the differentiated C1.19A cell line forms a resistive monolayer when grown on permeable supports and secretes C1 by the mechanism shown in Fig. 1 in response to elevated CAMP.Despite these qualitative differences in CAMP-dependent transport properties, these cell lines show identical quantities of CFTR expression at both the mRNA and protein levels (Morris et al., 1992). The results of recent studies (Morris et al., 1994) have shown that the basis for this difference in CAMP-activated CI conductance is in the differentiationdependent cellular location of CFTR. Undifferentiated colonic cells retain the protein in a perinuclear location as visualized by immunofluorescence. This site of CFTR retention must be at the level of the trans-Golgi network or sorting endosomes since the CFTR protein is fully glycosylated. In contrast, differentiated HT-29 cells target CFTR to the polarized apical membrane domain. The signals responsible for retention of CFTR in the undifferentiated cells appear to be epithelial cell specific, inasmuch as the recombinant protein, when expressed in heterologous systems (e.g. fibroblasts), targets out to the plasma membrane and is cAMP responsive (Cheng et al., 1990; Yang et al., 1993). Thus, the signals which permit apical targeting of CFTR in epithelial cells appear to be expressed in
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concert with those that generate cellular polarization, the formation of tight junctions, and discrete apical and basolateral membrane domains. Other apical membrane proteins target in a polarization-dependent fashion (Rodriguez-Boulan and Nelson, I989), and CFTR apparently falls into this category. 5. Regulation of GcFP
The changes in the electrical potential profile of secretory cells that are evoked by an increase in cellular cAMP show that the primary event in stimulation of C1 secretion is an increase in apical membrane CI conductance. This is usually followed or accompanied by an increase in basolatera1 membrane K conductance (Welsh ef al., 1982). In intestinal and airway cells, this secondary K conductance change is thought to be important in enhancing the driving force for CI exit by depolarizing the cellular electrical potential profile, particularly the apical membrane voltage (Welsh et al., 1983; Smith and Frizzell, 1984). The secondary K conductance change does not occur in all systems. Both microelectrode and whole-cell patch-clamp studies of HT-29 cells have revealed evidence of the C1 conductance activation without a corresponding K conductance change (Bajnath et al., 1991). Interestingly, the undifferentiated nonpolarized HT-29 cells show evidence of a CAMP-mediated K conductance change which appears to be absent in the differentiated CI. 19A subclone. The increase in both apical CI and basolateral K conductance observed in airway epithelia is found in both native tissue and primary cultures of the epithelial cells. However, evidence suggests that cAMP can evoke an increase in intracellular Ca (McCann et al., 1989a) so that in some cell types the increase in basolateral K conductance may be induced by a CAMP-induced cellular Ca rise. Activation of protein kinase C by phorbol esters induces C1 secretion across both intestinal and airway epithelia (Chang et a/., 1985; Fondacaro and Henderson, 1985; Barthelson et a / . , 1987). However, much of the C1 secretion elicited by phorbol esters could be blocked by indomethacin (Musch et a / ., 1990), suggesting that the activation of PKC is also accompanied by prostaglandin formation and the stimulation of cAMP production. Studies have shown clearly that C1 secretion can be induced by the phorbol ester PMA in the presence of indomethacin (Barthelson et a/., 1987) and, in HT-29 C1.19A cells, stimulation by phorbol ester or carbachol results in transloc,ation of PKC from cytosolic to membrane fractions (Van den Berghe et a / . , 1992). In some cell culture systems, conflicting results have been obtained for phorbol ester stimulation of C1 secretion and this may be related to the expression of different PKC isoforms in different cell lines or under different culture conditions.
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A number of studies have implicated activation of the same C1 conductance by PKC and PKA. In a study of CFTR phosphorylation by forskolin and phorbol ester, Picciotto et al. (1992) found multiple phosphorylation sites arising from CAMP stimulation, but only a subset of these were cophosphorylated by PKC. In addition, PKC was found to phosphorylate a residue in the R-domain that was not PKA sensitive. The activation of CFTR CI channels has been found to follow a pattern which could be explained on this basis (Tabcharani et a / . , 1991). Channel activity stimulated by PKC alone was much smaller than that observed with PKA, but together their effects on Po potentiated one another. Thus, phosphorylation at the PKC sites may have only a marginal effect on CI channel activity, but when combined with PKA, the additional PKC-induced phosphorylation may greatly potentiate the activity of CFTR (Tabcharani et al., 1991). In other studies, synergism between PKA and PKC in excised patches has not been found (Berger et al., 1993). The differences in these findings could stem from the study of endogenous vs exogenously expressed CFTR or from the use of epithelial vs nonepithelial cells. cGMP also activates C1 secretion and has been most extensively studied in colonic epithelial cell lines (e.g., T84) (DeJonge and Rao, 1990). An interesting aspect of this activation process is that these cells express no cGMP-sensitive protein kinase activity, and therefore the effects of elevated cGMP are thought to reflect activation of protein kinase A. The cGMP levels achieved in response to stimulation are sufficient to activate PKA. Nevertheless, it has been shown that in uitro phosphorylation by protein kinase G is capable of activating a low-conductance C1 channel in membrane patches excised from T84 cells (Lin et al., 1992). In intestinal cells, DeJonge et ul. (1993) have shown that the activation of a specific PKG isoform (type 11) is associated with C1 conductance activation. Therefore, in systems where protein kinase G is expressed, there is every reason to believe that CFTR would be a phosphorylation substrate for this kinase. B. The Ca-Activated CI Conductance: G$J
A second class of secretory agonists uses increases in intracellular Ca to stimulate C1 secretion, and they include muscarinic agonists, histamine, bradykinin, and neurotensin. In general, these agents stimulate a transient secretory response, in contrast to the sustained activation induced by CAMP-mediated agonists. The transport and regulatory mechanisms responsible for Ca-mediated C1 secretion, and for its transient nature, are beginning to be identified.
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1. Properties of the Macroscopic Whole-Cell Current ( 1 . Time und Voltage Dependence. During both depolarizing and hyperpolarizing voltage pulses, the currents activated by increased cell Ca show time-dependent behavior (Cliff and Frizzell, 1990; Morris er d., 1990; Anderson and Welsh, 1991; McDonald et al., 1992). With an initial holding voltage of 0 mV, the currents observed at depolarizing voltages activate. whereas those recorded at hyperpolarizing voltages inactivate (Fig. 4A). This behavior clearly differs from that associated with cAMP activation where the currents are time independent; however, in some cell types (e.g.. T84 cells) the time dependence of G$ wanes with time after stimulation and more closely resembles the currents activated by cAMP (W. H. Cliff and R. A. Frizzell, personal observation). Since total current is the product of the single-channel conductance, channel number, and channel open probability ( P o ) ,it is useful to minimize the timedependent inactivation of G$ by using a conditioning prepulse that maximizes P,, (in this case, a large depolarizing voltage). The instantaneous currents can then be recorded at various test voltages before timedependent changes in current intervene. Following a conditioning prepulse to + 100 mV (Fig. 4B), the currents recorded at progressively more depolarized voltages inactivate, and the steady-state current-voltage relation is outwardly rectified. However, the instantaneous currents show a near-linear current-voltage relation, which should reflect the currentvoltage relation of the underlying single-channel events. Thus, the Z-V of the macroscopic currents traversing G E is markedly dependent on the voltage prehistory of this conductance pathway. Fig. 4C illustrates this phenomenon in terms of the current-voltage relations shown for two different holding voltages, 0 and + 100 mV. Currents determined from an initial holding potential of 0 mV show marked outward rectification because G E is partially inactivated at this voltage. Further depolarization activates additional current, while hyperpolarization produces voltagedependent inhibition of current flow. On the other hand, the instantaneous currents recorded from a holding potential of + 100 mV show a nearly linear I-V relation, which turns out to be similar to the Z-V of the underlying single-channel events (see below).
b. i o n Selectivity. The Na/CI selectivity of the Ca-activated CI conductance is approximately 0.14 (Anderson and Welsh, 1991). Inasmuch as the data shown in Fig. 4 were obtained in the absence of permeant cations, the current properties shown reflect those of the G$. The halide selectivity sequence obeys Eiseman sequence I selectivity:
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0.5 nA
0 mV prepulse
i 100 ms
B a-0
Instantaneous
A-A
Stdy. state
-- 1.5 -1 00
/*
-.0.5
-50 0-
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-0.5 -
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i
/
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100 mV
FIGURE 4 Properties of the GE!. The upper panels (A.C) show an overlay of wholecell currents from a T84 cell during voltage pulses to ? 100 mV during steady-state stimulation by 5 N M ionomycin in the presence of a I m M bath Ca. Currents in A were obtained with a 0-mV prepulse voltage in which GEY is partially inactivated. Accordingly. the instantaneous and steady-state currents (B) show marked outward rectification. Currents in C were obtained following a prepulse to t 100 mV to activate GET. Under these conditions, the instantaneous currents (D) are nearly linear, conforming to the properties of the single-channel events activated by a cellular Ca rise (see text).
I > Br > C1 > F (Cliff and Frizzell, 1990; Anderson and Welsh, 1991) and, as for other anion conductances that have been examined, the degree of selectivity among the halide anions is not large (e.g., P,IPa 2).
-
c. Blocker Sensitivity. The Ca-activated C1 conductance is inhibited by the disulfonic stilbenes, i.e. DIDS and DNDS (Anderson and Welsh, 1991). The outward currents are principally affected by DIDS (R. T. Worrell and R. A. Frizzell, personal observation). The sensitivity of this
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C
0.5 nA
+lo0 rnV prepulse
I 35 ms
conductance pathway to other classes of C1 channel blockers (anthracene and ethacrynic acid homologues) has not received much attention, although NPPB was reported to inhibit an acetylcholine-induced C1 current in trachael cells (Winding et al., 1992). 2. Single-Channel Basis of GE A number of studies suggest that CFTR is not responsible for the Caactivated C1 conductance: (a) G$j is present in cells that express little or no CFTR (Wine et al., 1991), (b) the conductances activated by Ca and CAMP exhibit distinctly different properties (see above), including differences in kinetics, time and voltage dependence, and blocker sensitivity and their currents are additive (Cliff and Frizzell, 1990), (c) the Ca-activated C1 secretion is normal in cystic fibrosis airway cells whereas C1 secretion
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elicited by CAMP-dependent mechanisms is absent (Frizzell et a/., 1986; Welsh and Liedtke, 19861, and (d)the Ca-activated conductance is present in undifferentiated intestinal cells where no CAMP-activated channels are found due to restrictions on CFTR targeting into the plasma membrane (Morris et al., 1992). Studies have identified a Ca-activated CI channel in HT-29 cells, during both cell-attached and excised patch recording (Morris and Frizzell, 1993a,b). The properties of these channels differ from those associated with CFTR. CI channels were activated when membrane patches were excised into solutions containing high (1 pLM) Ca concentrations. With equal CI concentrations bathing both membrane surfaces, the I-V relation of the single-channel events was slightly outwardly rectified (as are the instantaneous whole-cell currents, see above). The single-channel chord conductance averaged 13 pS at -90 mV and 16 pS at +90 mV. As with the Ca-activated whole-cell currents, the single-channel events showed time-dependent activation at depolarizing membrane voltages. During cellattached recording, CI channel activity was rarely observed at resting Ca levels, but channels with the same properties as those found in excised patches were activated in response to the Ca ionophore, ionomycin, or the Ca-dependent agonist, neurotensin. When cell-attached patch-clamp measurements were combined with simultaneous intracellular Ca determinations, C1 channel activation correlated in time with the Ca rise induced by ionomycin. With the Ca-mediated agonist, neurotensin, CI channel activation preceded the generalized cellular Ca rise, as reported previously for the whole-cell CI current evoked by neurotensin (Morris et al., 1990). These simultaneous measurements indicate that Ca-dependent agonists release Ca from peripheral stores in the vicinity of the plasma membrane, whereas the Ca rise produced by ionophore is more homogeneous. The Ca dependency, voltage and time dependence, and kinetics of the -15-pS CI channel indicate that it is the basis of the Ca-activated whole-cell CI current. When patches containing this 15-pS CI channel are excised from the cell, its activity decreases, or runs down (Morris and Frizzell, 1993b). Cell-attached channel activity recorded from detergent-permeabilized cells shows a similar phenomenon. Thus, it appears that an essential cellular regulatory factor(s) may be lost upon patch excision or membrane permeabilization. In some studies, this may occur as a result of cell dialysis during conventional whole-cell recording, leading to a loss of function of these Ca-dependent CI channels (Devor et a [ . , 1993). After run-down of the 15-pS channel, a large conductance multistate C1-selective channel (maxi-C1 channel) is observed. This channel is Ca insensitive. Maximal single gating events of this channel yield current transitions corresponding
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to a conductance of approximately 200-300 pS. However, this maxichannel shows complex subconductance behavior, in which the smallest subconductance state is similar in magnitude to the conductance of the Cadependent CI channel (-IS p s ) . In addition, the voltage sensitivity and halide selectivity of this maxi-CI channel are also similar to those of the 15-pS channel and the Ca-dependent whole-cell Cl currents. Activity of this maxi-CI channel has not been observed in intact cells, nor were the large and small channels observed simultaneously. Its substate behavior with similar properties suggests that this maxichannel may be a functionally altered remnant of the Ca-sensitive IS-pS CI channel, but cloning and expression studies will probably be necessary to verify this idea. The molecular basis of (3% is unknown, but there are some interesting leads in this direction. The properties of (3% do not correspond to the properties of already cloned CI channels when these are expressed in heterologous systems (Frizzell and Cliff, 1992). However, Ran and Benos (1991) have reconstituted a CI channel from bovine tracheal apical membranes whose properties are interesting with respect to GZ. The singlechannel conductance, anion selectivity, and stilbene sensitivity of this channel in planar lipid bilayers are in rough agreement with those of the Ca-activated CI channel discussed above (Ran et a / . , 1992). Its activity appears to depend on disulfide bond interactions and can be abolished by dithiotheitol (DTT). Interestingly, DTT blocks the 'IsI efflux from T84 monolayers stimulated by Ca ionophore, but not that evoked by forskolin (C. M. Fuller and D. J . Benos, personal communication). An antibody has been raised to the 38-kDa protein that was used in the reconstitution studies, and it should be useful in attempts to further characterize this channel's structural properties. 3. Regulation Activation of the 15-pS channel by Ca-mediated agonists does not require bath Ca; however, the agonist effects are abolished by preloading cells with BAPTA (Morris and Frizzell, 1993b). Thus, agonist-induced activation of this C1 channel involves mobilization of Ca from intracellular stores. Several studies have documented a stimulation of inositol polyphosphate hydrolysis and cellular Ca mobilization that mediates the actions of primary Ca-dependent agonists such as carbachol and neurotensin (Turner et a!., 1990; Morris er al., 1990; Devor et al., 1993). The activation of G z i n HT-29 cells by neurotensin could be abolished by loading the cells with a synthetic peptide corresponding to the calmodulin binding domain of the Ca/calmodulin-dependent protein kinase I1 (Morris and Frizzell, 1993b). This competitive antagonist of calmodulin-mediated signaling inhibited CI channel activation without a corresponding effect
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on either agonist-induced Ca mobilization or activation of K conductance pathways. These results suggest that calmodulin confers Ca sensitivity to the 15-pS CI channel. Inhibitors of calmodulin’s interaction with its binding proteins, including trifluoperazine, calmidizolium, and sphingosine, also reversibly abolished the Ca-stimulated CI currents (Worrell and Frizzell, 1991). The addition of pseudosubstrate inhibitor peptides for various kinases to whole-cell patch pipettes has demonstrated that the Ca-activated Cl conductance is not altered by inclusion of the peptide inhibitors of protein kinases A or C, but that the peptide inhibitor of Calcalmodulin-dependent protein kinase I1 (CaMKII283-302) specifically abolishes the activation of G g in both T84 cells and lymphocytes (Worrell and Frizzell, 1991; Wagner et al., 1991). Truncated peptides lacking essential elements of the autoinhibitory domain or the Ca binding region were ineffective. These findings suggest that the Ca/calrnodulin-dependent protein kinase I1 activates GE in both epithelial and nonepithelial cells. At present, it is not clear whether this represents a direct effect of the kinase on the 1.5-pS CI channel or whether other proteins are also involved in transducing this signal.
4. Occurrence and Location A Ca-activated C1 conductance with the properties cited above is found in a variety of secretory epithelial cells, including colonic and pancreatic cell lines and primary cultures of airway, nasal, and sweat gland epithelial cells (Cliff and Frizzell, 1990; Wagner et al., 1991; Anderson and Welsh, 1991). It is also present in certain nonepithelial cells, e.g., lymphocytes, where activation of a C1 conductance with similar conductance and kinetic properties has been demonstrated in response to Ca ionophores (McDonald et al., 1992). It has also been suggested that the Ca-mediated activation of CI conductance in the G, phase of the cell cycle is a feature of lymphocyte proliferation; several steps in this process are Ca dependent (Bubien et al., 1993). The cellular location of G g in epithelial cells and its role in Ca-mediated C1 secretion has been the focus of some studies. According to the model of Dharmsathaphorn and colleagues (Cartwright et al., 1983, Ca-mediated agonists stimulate C1 secretion across the apical membrane through an already open CI conductance. An increased rate of C1 exit across the apical membrane is driven by hyperpolarization of the cellular electrical potential profile produced by a primary Ca-dependent activation of the basolateral K conductance. This idea has gained additional support from several observations. Anderson and Welsh (1991) showed that when the basolateral membranes of confluent T84 cells were permeabilized by nystatin in the presence of a transepithelial C1 gradient, no Ca-stimulated C1
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current was detected. However, a transapical C1 current was stimulated by CAMP.They concluded that the Ca-stimulated C1 conductance detected in whole-cell recordings is present in subconfluent cells, but is not expressed once the cells polarize. Accordingly, the Ca-dependent secretory response would depend on basal activity of the GcYPand K channel activation. Morris el al. (1993) lent further support to this idea in experiments with BFA, an inhibitor of glycoprotein targeting to plasma membranes. They showed that BFA abolished the CAMP-activated C1 secretory response across HT-29 monolayers with a time course similar to that for the retrieval of CFTR from the apical membrane domain. The Ca-activated C1 secretory response was small and unaffected by BFA. When a Camediated agonist was added during stimulation by CAMP. the additional secretory response to Ca was large, but like the CAMP-activated secretory response, the secretion evoked by Ca with cAMP present was abolished by BFA. This suggests that the apical C1 conductance pathway stimulated by cAMP is dominant under conditions where Ca and cAMP are acting together. Thus in many epithelia, and especially in cells of intestinal origin, CFTR may play a major role in establishing the apical CI conductance for Ca-dependent C1 secretion. Indeed, this would account for the observation that both cAMP and Ca-mediated C1 secretion are defective in the intestinal epithelia from cystic fibrosis patients (Berschneider et al., 1988; Goldstein et al., 1988). Since CFTR accounts for GcYP, basal C1 conductance activity of CFTR must play a major role in intestinal secretion activated by Ca. Other studies suggest that a Ca-stimulated C1 conductance is expressed in the apical membranes of intestinal cells. Evidence from microelectrode studies has shown that Ca-stimulated C1 conductances are present at both the apical and basolateral membranes of polarized HT-29 cells (Bajnath et al., 1992). Moreover, when these cells were treated with nystatin, the C1 conductance response to ionomycin at the apical membrane was lost, but the response to forskolin was still present. These results suggest that the experimental conditions used to monitor transapical C1 currents, permeabilization of the basolateral membranes with nystatin, may interfere with the CI conductance response to Ca. Additional evidence of an apical G$j in intestine was provided by Morris et al. (1992) who found that the 15-pS C1 channel in the apical membranes of confluent monolayers of HT-29 cells was activated by ionomycin and neurotensin during cell-attached recording. Their data show a higher density of the 15pS Ca-activated C1 channel in undifferentiated, unpolarized HT-29 cells than in the polarized subclone. Thus, the Ca-activated channel targets to the plasma membrane in the absence of cellular polarization, and its targeting and/or expression level may fall as intestinal cells take on
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more differentiated functions. This pattern is the converse of that associated with apical membrane CFTR expression. It should probably not be surprising to find cells at intermediate levels of differentiation where both GcTP and G$j are present in the apical membrane. The HT-29 (CI. 19A) cells appear to express both pathways when polarized: T84 cells may not. In contrast to the results from intestinal epithelia, studies of airway epithelia have indicated that Ca-mediated CI secretion is not affected in cystic fibrosis (Boucher ef d.,1989; Willumsen and Boucher, 1989). Both transepithelial transport and microelectrode studies have shown that Ca ionophores and primary Ca agonists increase the Cl conductance of the apical membrane. It will be interesting to determine whether the 15-pS CI channel identified in intestinal cell lines is expressed also in the apical membranes of airway cells. It is possible that the cellular targeting controls on the Ca-dependent Cl channel differ in airway and intestinal cells, so that Ca-dependent CI secretion is less dependent on CFTR function at the apical membranes of airway cells. The pharmacologic manipulation of Ggin airway cells represents a potential therapeutic approach to providing a missing Cl secretory conductance in the airways (Knowles e? a / . , 1991; Stutts et al., 1992). C. Combined €Heels of cAMP and Ca
The combined effects of Ca and cAMP on whole-cell C1 currents are additive (Cliff and Frizzell, 1990; Anderson and Welsh, 1991).The currents stimulated by cAMP show characteristic time-independent. ohmic properties, and Ca stimulates an additional C1 current component having the time-dependent properties of activation at depolarizing voltages that are characteristic of Gg. The additivity of these currents fits with the idea that separate conductance pathways and different single channels are responsible for the effects of cAMP and Ca. As noted earlier, the combined effects of Ca and CAMP-mediated agonists on transepithelial C1 transport are more than additive. When both cAMP and Ca are elevated, a potentiated or synergistic response occurs in which the rate of C1 secretion exceeds the sum of the individual responses. Potentiation of the secretory response has been observed in a variety of epithelial tissues and cultured cell monolayers (Cartwright et al., 1985, Yajima et al., 1988; Barrett and Dharmsathaphorn, 1990; Simmons, 1992). As mentioned previously, the basis of potentiation between cAMP and Cadependent agonists lies in the primary activation of different conductance
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pathways by these second messengers. cAMP acts primarily on apical CI conductance whereas Ca acts primarily to increase the basolateral K conductance and hyperpolarize the apical membrane potential. Studies have utilized the sustained vs transient nature of the transepithelial response to secretagogues to categorize them as cAMP or Ca mediated (Madara et a / . , 1992). Combining secretagogue additions to probe for potentiation with agonists that are known to operate through cAMP or Ca can provide a preliminary categorization of the second-messenger and conductance pathways activated by an agonist whose mechanism of action is unknown. Whole-cell current measurements suggest that this potentiated response is not due to interactions between GcYPand GE. Rather, it derives from Ca activation of the basolateral membrane K conductance and an increase in the driving force for apical C1 exit. A Ca-dependent K channel in the basolateral membranes of airway and intestinal cells that appears to be responsible for this response has been identified (McCann et a / . , 1990; Devor and Frizzell, 1993). This inwardly rectified K channel shows a similar pharmacological profile to that determined previously from measurements of transepithelial C1 secretion (Barrett and Dharmsathaphorn, 1990). During cell-attached recording from T84 cells, it was activated by the Ca-dependent agonists carbachol, ionomycin, and taurodeoxycholate (Devor and Frizzell, 1993).
111. THE VOLUME-SENSITIVE CI CONDUCTANCE: G$
Following an initial cell swelling, cells exposed to hypotonic media generally undergo a regulated return toward their original size (Grinstein and Foskett, 1990). This regulatory volume decrease (RVD) is caused by the activation of conductance pathways for CI and/or K , which elicits KCI exit. Water follows osmotically to effect a reduction in cell volume. In both lymphocytes and epithelial cells, cell swelling and CI conductance activation occur during conventional whole-cell patch clamp (Cahalan and Lewis. 1988; Worrell et ol., 1989). The CI conductance activation can be enormous as cells continue to swell under these conditions. Both the volume increase and the CI conductance activation can be reversed by imposing a suitable osmotic pressure difference between the pipette and bath solutions. In some cells (e.g., T84). the imposition of an osmotic gradient between the bath and the pipette is necessary to prevent cell swelling and provide a low basal cellular conductance upon which the effects of secretory agonists (as above) can be discerned (Cliff er a/., 1991).
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A. Properties of the Whole-Cell Current
The swelling-activated C1 conductance shows unique biophysical properties that permit its distinction from the agonist-activated C1 conductances (Worrell et al., 1989; Wagner er al., 1991; McDonald er al., 1992). The C1 currents evoked by cell swelling are outwardly rectified, and during both hyperpolarizing and depolarizing voltage pulses, they exhibit time dependence. This property differs from GE, in that the currents inactivate during depolarizing voltage pulses and activate with hyperpolarization of the membrane potential (Fig. 5A). Accordingly, and as with GE, the shape of the current-voltage relation is influenced by the degree to which this conductance pathway is activated prior to voltage clamp. Nevertheless, even when GE' is maximally activated by conditioning prepulses to large negative voltages, the instantaneous currents recorded at progressively more depolarized voltages are outwardly rectified (Fig. 5B). The source and potential function of this time dependence of the currents are not known, but it appears to be an inherent and stable feature of this conductance pathway at all times subsequent to activation.
1. Anion Selectivity The properties illustrated in Fig. 5 are characteristic of the C1 conductance activated by cell swelling inasmuch as the currents are recorded in the absence of permeant cations. As with GE, the halide-selectivity sequence obeys the Eiseman I series, I > Br > C1 > F, and as for the other anion conductances, differences in anion permeability are not large (Worrell et al., 1989). 2. Blockers The swelling-induced conductance is sensitive to the disulfonic stilbenes, DIDS and DNDS, which block these currents with ICso values of approximately 5 p M (R. T. Worrell and R. A. Frizzell, personal communication; Solc and Wine, 1991). Interestingly, DIDS added to the bath under whole-cell recording conditions blocks primarily the outward currents (C1 entry) with little effect on inward C1 currents (C1 exit). Over brief periods of exposure (1-2 min), DIDS was a reversible inhibitor; nevertheless, the sensitivity of these currents to DNDS suggests that the disulfonic stilbene effect is due to specific channel block. Other studies (McCann er a/., 1989b) showed that the GE' can be inhibited by diphenylamine-2-carboxylicacid (DPC) and 5-nitro-2-(3-phenylamine) benzoate (NPPB). The pattern of block is similar to that observed for the outwardly rectified C1 channel (ORCC). Evidence that the ORCC may account for the swelling-activated C1 conductance will be presented below.
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A
.2 nA
I .5 sec
B
~ 3 . 5nAf20pF
1
-1.5 1 FIGURE 5 Properties of GZP'. (A) Currents recorded during steady-state cell swelling at membrane voltages between t 100 mV. (B) Instantaneous (circles) and steady-state (triangles) I-V relations of GZP'. In this experiment, a holding potential of - 100 mV was used to activate these currents prior to the test pulse.
8. Occurrence and Location
The swelling-activated C1 conductance has been observed in a variety of epithelial and nonepithelial cells. In epithelia, it was first identified in the colonic tumor cell line, T84, but it is also present in other intestinal cells (Hazama and Okada, 1988) in the pancreatic cell lines, Panc-1 and CFPAC, and in primary cultures of airway and sweat gland cells. There is no discernible difference in (3%' recorded from C F and non-CF cells (Solc and Wine, 1991; Wagner et a f . ,1991; McDonald etal., 1992; McCann et al., 1989b; R. T. Worrell and R. A. Frizzell, personal communication). In nonepithelial cells, the properties of this conductance have been most
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Raymond A. Frizzell and Andrew P. Morris
completely characterized in human T lymphocytes (Cahalan and Lewis, 1988; McDonald et al., 1992) and Xenopus oocytes (Parker and Miledi, 1988).The current-voltage relations and kinetics of the swelling-activated C1 conductance are qualitatively similar in all systems examined (Fig. 5 ) . The location of this swelling-induced conductance in epithelial cells is somewhat uncertain. Studies by McCann ef nl. (1989b), using tracheal cells in primary culture, suggest that at least some of these channels are located in the apical membrane. In these studies, tracheal cell monolayers were mounted in Ussing chambers and swelling was elicited by exposure to hypotonic media. The development of a short-circuit current suggested stimulation of an apical membrane C1 conductance. ORCC have been recorded from the upward-facing membranes of T84 cells in islands. In addition, a swelling-induced K conductance lies in the basolateral membrane and its activation could lead to C1 secretion via already active apical C1 conductance pathways (e.g., as in the response to Ca-dependent agonists). The localization question should be reexamined in confluent cell monolayers on permeable supports or using transepithelial current measurements in monolayers where the apical or basolateral membranes are permeabilized with nystatin or amphotericin. The activation of singlechannel events or transepithelial currents with the appropriate voltagedependent kinetics in response to cell swelling would clearly indicate an apical location. However, inasmuch as these channels are also present in nonepithelial cells, it seems likely that they reside, at least in part, in the basolateral membranes.
C. Regulation The intracellular mediator(s) of GE1are poorly characterized and may vary among different cell types. For example, in intestinal 407 cells, CI conductance activation during swelling requires Ca, but the GE' is insensitive to intracellular Ca concentration (Hazama and Okada, 1988). Similar results are obtained from T84 cells in which the development of G$ is still present at high EGTA concentrations in pipette and bath (calc. cell Ca 25 nM, Worrell et al., 1989). In HT-29 cells, simultaneous whole-cell conductance and Ca measurements showed no increase in cell Ca as C1 currents developed during cell swelling (A. P. Morris and R. A. Frizzell, unpublished observation). Arachidonic acid metabolites appear to be important in activating the swelling conductance in some cell types, e.g., lymphocytes (Lambert, 1987). RVD was accelerated by exposure of lymphocytes to leukotriene D, and inhibited on exposure to arachidonic acid (Lambert, 1989). Preliminary experiments showed inhibition of the Cl
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conductance response by NDGA in T84 cells (R. T. Worrell and R. A. Frizzell, unpublished observation). In the presence of the lipoxygenase inhibitor, cells swell in hypotonic media, but C1 currents do not develop. These findings suggest that an arachidonic acid metabolite, perhaps a leukotriene, mediates the activation of GE'; its generation could be controlled by membrane deformation, or in systems where cell Ca rises in response to swelling, by Ca-induced activation of phospholipase A,. It would be interesting to attempt to uncouple the conductance response from the volume stimulus with PLA, inhibitors. D. Single-Channel Basis
The single-channel event responsible for the swelling-induced C1 current appears to be a mid-sized C1 channel of -50 pS (at 0 mV), which shows voltage-dependent kinetic properties similar to those of the whole-cell swelling-induced current (Worrell et a / ., 1989; Solc and Wine, 1991; Banderali and Roy, 1992). This channel is active at hyperpolarizing voltages, and test pulses to depolarizing voltages produce step-wise inactivation of single-channel currents (Worrell et al., 1989). Summation of many such single-channel records yields an ensemble current whose inactivation time constant matches that of the swelling-induced whole-cell current. Singlechannel events with these properties have been observed during both cellattached and excised inside-out recordings from swollen cells but their activity drops after seal formation (run-down) (Solc and Wine, 1991; Banderali and Roy, 1992). A member of the transport ATPase family related to CFTR is the Pglycoprotein, the product of the multiple drug resistance gene, mdrl. Valverde et al. (1992) found that the swelling-induced whole-cell C1 currents in fibroblasts expressing mdrl were much larger than those in nontransfected cells. They suggested that mdrl encodes the channel responsible for GZ'. A compelling feature of their findings was the inhibition of swelling-induced currents by P-glycoprotein transport substrates. These authors have suggested (Valverde et al., 1992)that P-glycoprotein is obligatorily bifunctional and that its drug transport or channel functions may be separated by hydrolyzable vs nonhydrolyzable ATP analogues. Whereas drug transport requires ATP hydrolysis, channel function apparently can be supported by nucleotide binding. Resolution of whether Pglycoprotein is responsible for GE' will require more detailed studies, as was true of CFTR. In particular, single-channel measurements would permit direct assessment of the relation to ORCC, more detailed studies of drug interactions, and structure-function studies. Reconstitution of the purified protein would be the ultimate goal.
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N. THE OUTWARD RECTIFIER In recent years, much attention has been focused on the properties of a -40-pS outwardly rectified CI-selective channel that is present in a variety of cell types. The distinctive biophysical features of this channel and its relatively large unitary currents facilitated its identification in trachea (Welsh and Liedtke, 1986; Frizzell et al., 1986), sweat gland (Wine et al., 1991), colon (Halm et al., 1988), and pancreatic cells (Schoumacher et al., 1990).A channel with similar properties has been detected in human skin fibroblasts and lymphocytes (Bear, 1988; Chen et al., 1989). Its biophysical properties have been described in detail (Halm and Frizzell, 1992).
A. ion Selectivity The selectivity for C1 over Na found in several cell types varies between 10 and 100 for Pa/PN,. The relative halide anion permeabilities of the outward rectifier (Halm and Frizzell, 1992), as determined from bi-ionic reversal potential measurements, is I (1.7)/Br (1.4)/C1 ( 1 .O)/F = HC03 (0.4). As determined from conductance measurements, I, Br, and CI are equally effective current carriers for anion efflux (the secretory current). The conductance ratios for HC03and F (relative to C1) are -0.4 (Tabcharani et al., 1989; Kunzelmann et al., 1991a). The open probability of the outward rectifier increases with membrane depolarization. Thus, Po increases as the cytoplasmic side is made more positive and may increase as much as fivefold between -80 and +80 mV (Halm et al., 1988).
B. Blockers Compounds of three chemical classes have been shown to block this C1 channel. Derivatives of DPC were characterized for their inhibition of basolateral C1 conductance in renal tubules by Greger and colleagues (Wangemann et al., 1986). Their structure-activity studies led to the identification of NPPB, the most potent blocker in this assay. A second class of compounds was developed by Landry er al. (1987) based on the initial work of Cragoe with indanyloxy alkanoic acids (Cragoe et al., 1986). They identified IAA-94 (2-[(2-cyclopenytyl-6,7-dichloro-2,3-dihydio-2methyl- 1-oxo- lH-inden-5-yl)oxy]acetic acid) as the most potent inhibitor of Cl uptake into renal membrane vesicles. The third class of blockers is the disulfonic stilbenes, traditionally used to inhibit the anion exchanger
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in red cells. Bridges et af. (1989) and Becq et af. (1992) found that the ORCC was blocked by disulfonic stilbenes. DNDS (4,4’-dinitro stilbene2,2’-disulfonic acid) reversibly blocked the outwardly rectified C1 channel from rat colon incorporated into planar lipid bilayers with the characteristics of an open channel blocker. Finally, a channel with properties similar to those of the ORCC may be blocked by a scorpion venom toxin (DeBin and Strichartz, 1991). Bridges and co-workers (Singh et af., 1991) have now compared the potencies of the lead compounds from these three classes of anion channel antagonists in blocking the ORCC from rat colon in planar lipid bilayers and characterized their mechanism of block. NPPB and IAA-94 were equipotent when added to either side of the bilayer, and this probably reflects their high lipid solubilities. DNDS was about 10-timesmore potent as a blocker of the ORCC when added to the outside of the channel. NPPB caused a decrease in channel conductance (fast block), whereas the other compounds caused a flickery block (increased brief closures) that decreased Po. Perhaps most interestingly, no compound by itself could be used to infer a role for the ORCC in contributing to a macroscopic C1 current. The relative blocker potency order and sidedness of block would be needed to implicate the outward rectifier as contributing to a whole-cell or transepithelial C1 current. Kinetic analysis suggested that these compounds act as open channel blockers. While decreasing Po within open bursts of channel activity, these compounds increased burst duration. This may account for their relatively weak effects on transepithelial C1 secretory currents. Caution also is warranted in interpreting the effects of these compounds on macroscopic currents, since all of these agents influence other transport and cellullar processes. At present, highly selective reagents that would permit distinction of different Cl channels or conductance pathways based on the actions of C1 channel blockers alone have not been identified. Nevertheless, G:?’ and exhibit sensitivity to the disulfonic stilbenes while G$tMPdoes not. Accordingly, the absence of an effect of the reversible blocker, DNDS, could be useful together with other evidence to infer that CFTR contributes to a whole-cell or transepithelial secretory CI current. Newly developed and more potent relatives of these compounds, the calixarenes, should be even more useful in this regard (Singh el af., 1993). C. Regulation
In most studies, secretory agonist-induced activation of the outward rectifier during cell-attached recording has not been detected (see, however, the report of Henderson et al., 1992). It is now generally thought
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that the outward rectifier is active in excised membrane patches (however, see Volume-Activated C1 Channels; Solc and Wine, 1991). Most studies of the outward rectifier and its regulation have been performed in patches excised from activated cells. Early conclusions regarding the cystic fibrosis phenotype involved studies of the regulation of the outward rectifier, both in (presumably) cellattached and in excised membrane patches. A consistent finding in four different laboratories (Frizzell et al., 1986; Welsh and Liedtke, 1986; Hwang et af., 1989; Chen et al., 1989) was the observation that PKA plus ATP activated the outward rectifier in excised patches from normal cells but not in patches derived from CF epithelial cells. Nevertheless, the low incidence of this channel in cell-attached patches has led to uncertainty regarding its role in contributing to secretagogue-mediated increases in apical C1 conductance. The lack of an effect of CAMP during cell-attached recording led to the idea that the outward rectifier might be tonically inhibited by a cytosolic factor and to the proposal that abnormal control over the cellular concentration of this factor might prevent activation of the channel in CF cells. Two groups have reported candidate cytosolic inhibitors of ORCC (Kunzelmann et al., 1991b; Krick et al., 1991). In addition, the cloning of the CF gene and its expression in both epithelial and nonepithelial cells focused attention on the low-conductance linear I-V channel observed in cells that endogenously and exogenously express CFTR, as discussed previously (see G:PMP). Yet, two reports confirm the regulatory differences in outward rectifier regulation observed in comparisons of normal and CF cells. These findings have again raised the idea that this channel is, in some way, under regulation by the CF gene product. In a study that repeats the protocols of experiments performed previously on primary airway cell cultures, Egan et al. (1992) found that PKA activated the outward rectifier in membrane patches excised from normal airway cell lines but not in patches excised from CF cell lines. The outward rectifier was not observed during cell-attached recordings; the small linear channel (CFTR) was present in cell-attached recordings from normal, but not CF, cells. Because of the low levels of CFTR expressed in these cell lines, the authors concluded that the outward rectifier was not related to the low-conductance CFTR CI channel, but was, in some way, regulated by CFTR in membrane patches where they coexisted. More recently, studies by Gabriel et al. (1993) have added additional intrigue to this puzzle. These investigators studied primary airway cell cultures from normal and CFTR “knockout” transgenic mice. These animals express no detectable CFTR mRNA or protein. The investigators excised membrane patches from both normal and CF cells into solutions containing PKA ATP. Under these conditions, outward rectifiers acti-
+
8. Salt Secretion in Epithelial Cells
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vated in patches derived from normal airway cells, but not in patches from CF cells. However, in the C F patches, the outward rectifier was present and could be activated by exposure to large depolarizing voltages (as in previous studies). Interestingly, this difference in regulation by PKA was also apparent in membrane patches that showed no detectable low conductance CI channel activity. This suggests that the CFTR C1 channel does not have to be present within the same membrane patch in order for the difference in PKA-dependent regulation of the ORCC to exist. These results are consistent with the idea that the C F gene product can regulate the activity of other proteins. Theories based on functional activity of CFTR in intracellular membrane compartments, where its activity could modify the processing and/or trafficking of other proteins, have been proposed (Barasch et al., 1991; Bradbury et al., 1992a). According to this hypothesis, the interactions between CFTR and other proteins may be indirect (e.g., as in the studies of Gabriel et al., 1993) and defects in this activity could affect a variety of other cellular processes which are thought to be manifestations of the C F phenotype (e.g., increased airway in Na absorption and changes in the composition of macromolecular secretory products). Further discussion along these lines, however, is beyond the scope of this review.
V. SUMMARY
From this discussion, it is evident that C1 conductances in secretory cells have been identified at a variety of levels of resolution. The role of secondary-active CI transport in salt secretion (Fig. 1) was identified from transepithelial measurements and the location of C1 conductances at the apical membranes was resolved using microelectrode recordings. The introduction of single-channel recording techniques generated candidates for the apical membrane secretory CI channel. However, the leap from the Ussing chamber to the patch pipette left in its wake considerable uncertainty as to the single-channel basis of the regulated C1 conductance pathways of secretory epithelial cells. Ultimately, whole-cell recording techniques bridged this gap and identified three regulated C1 current components, two of which are controlled by secretory agonists, the other by cell volume. The primary signal transduction events that control the activities of the secretory C1 conductances have emerged, but our understanding of their detailed modulation is incomplete. The mechanisms that mediate the swelling-induced C1 conductance appear to be complex and, perhaps cell specific. The distinct biophysical properties of these conductance pathways, summarized in Fig. 6 , together with the effects of blockers, suggest that different single C1 channels underlie each conductance
Raymond A. Frizzell and Andrew P. Morris
206 Kinetics
IV
fi (Inst.) 0 mv
Anion Selectivity
DIDS Block
1
Kinetics
Y=L 0 mv
IV
Anion Selectivity
DIDS Block
FIGURE 6 Summary of the whole-cell (left) and corresponding single-channel (right) properties of G$', G$y, and G;tMP.
pathway, and over the past several years, candidates for the single-channel basis of each conductance have emerged. Only in the case of CFTR, however, has the structural identity of a specific C1 conductance been verified by expression. Clearly, there remain many unknowns. Chief among these is the molecular basis of the Ca and volume-activated C1 conductances. Structural information on these channel proteins will provide the framework for an evaluation of their apical vs basolateral locations in epithelial cells and a description of their detailed mechanisms of regulation. The rapid growth of our understanding of CFTR, which has emerged since cloning of the CF gene, will provide a conceptual blueprint for similar studies of the Ca and volume-sensitive C1 channels.
Acknowledgments The authors are supported by NIH DK31091, DK38518, and DK41330. We thank Jan Tidwell for typing the manuscript, Edward Walthall for graphics, and Roger Worrell for help with the figures.
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Schoumacher. R. A., Ram, J., lannuzzi. M. C., Bradbury. N. A., Wallace. R. W.. Tom Hon. C.. Kelly, D. R.. Schmid, S. M.. Gelder, F. B., Rado, T. A.. and Frizzell. R. A . (1990). A cystic fibrosis pancreatic adenocarcinoma cell line. Proc. Nut/. Arad. Sri. U.S.A. 87(10). 4012-4016. Schultz. B. D.. Venglarik. C. J.. Bridges. R. J.. and Frizzell. R. A. (1993). Regulation of CFTR CI- channels by adenine nucleotide phosphates. FASEE J . 7(3).A426 (abstr.). Sheppard. D. N.. and Welsh. M. J . (1992). Effect of ATP-sensitive K' channel regulators on cystic fibrosis transmembrane conductance regulator chloride currents. J . Gen. Physiol. 100, 573-591. Silva. P.. Stoff. J.. Filed. M.. Fine, L., Forrest, N.. and Epstein. F. H. (1977). Mechanism of active chloride secretion by shark rectal gland: Role of Na-K-ATPase in chloride transport. Alll. J . Phvsiol. 233, F298-F306. Simmons. N. L. (1992). Acetylcholine and kinin augmentation of CI- secretion stimulated by prostaglandin in a canine renal epithelial cell line. J . Physiol. (London) 447, 1-15. Singh. A. K.. Afink. G . B., Venglarik. C. J.. Wang, R . . and Bridges. R. J. (1991). Colonic CI channel blockade by three classes of compounds. Am. J . Physiol. 260, C5I-C63. Smith, P. L.. and Frizzell. R . A. (1984). Chloride secretion by canine tracheal epithelium. IV. Basolateral membrane K permeability parallels secretion rate. J . Metnbr. B i d . 77, 187-199, Solc. C. K., and Wine, J. J. (1991). Swelling-induced and depolarization-induced CI- channels in normal and cystic fibrosis epithelial cells. Am. J . Physiol. 261, C658-C674. Sorscher. E. J.. Fuller, G . M.. Bridges, R. J . . Tousson, A.. Marchase. R. B.. Brinkley, B. R., Frizzell. R. A . , and Benos. D. J. (1992). Identification of a membrane protein from T84 cells using antibodies made against a DIDS-binding peptide. A m . J . Physiol. 262, C136-CI47. Stutts. M. J.. Chinet. T. C.. Mason. S. J . , Fullton. J . M., Clarke. L. L., and Boucher. R. C. (1992). Regulation of CI- channels in normal and cystic fibrosis airway epithelial cells by extracellular ATP. Proc. N d . A d . Sci. U.S.A. 89, 1621-1625. Tabcharani. J. A,. Jensen. T. J., Riordan, J. R.. and Hanrahan, J. W. (1989). Bicarbonate permeability of the outwardly rectifying anion channel. J . Membr. B i d . 112, 109122. Tabcharani. J . A.. Low, W.. Elie. D..and Hanrahan. J. W. (1990).Low-conductancechloride channel activated by CAMP in the epithelial cell line T84. FEES L e t / . 270, 157-164. Tabcharani. J. A,, Chang, X.-B.. Riordan. J . R . . and Hanrahan. J . W. (1991). Phosphorylation-regulated CI- channel in CHO cells stably expressing the cystic fibrosis gene. Nufirre (London)352, 628-63 I . Tabcharani. J. A,. Chang. X.-B.. Riordan. J. R., and Hanrahan, J. W. (1992). The cystic fibrosis transmembrane conductance regulator chloride channel. Iodide block and permeation. Biophys. J . 62, 1-4. Thomas. P.J.. Shenbagamurthi. P.. Ysern. X . . and Pedersen. P. L. (1991). Cystic fibrosis transmembrane conductance regulator nucleotide binding to a synthetic peptide. Science 251, 555-557. Trapnell. B. C.. Zeitlin. P. L.. Chu. C. S.. Yoshimura, K.. Nakamura. H . , Guggino, W. B.. Bargon, J., Banks, T. C.. Dalemans. W., Pavirani. A , . and Crystal, R. G . (1991). Down-regulation of cystic fibrosis gene mRNA transcript levels and induction of the cystic fibrosis chloride secretory phenotype in epithelial cells by phorbol ester. J . B i d . Clwm. 266, 10319-10323. Turner. J. T.. James-Kracke. M. R.. and Camden. J. M. (1990).Regulation of the neurotensin receptor and intracellular calcium mobilization in HT29 cells. J . Phartnucol. Exp. Ther. 253, 1049-1056.
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Valverde. M. A., Diaz. M., Sepulveda, F. V.. Gill, D. R., Hyde, S. C., and Higgins, C. F. (1992). Volume-regulated chloride channels associated with the human multidrug resistance p-glycoprotein. Nature (London) 355, 830-833. Van den Berghe. N.. Vaandrager, A. B., Bot, A. G. M., Parker, P. J., and DeJonge, H . R. (1992). Dual role for protein kinase C (x as a regulator of ion secretion in the HT29 c1.19A human colonic cell line. Biochem. J . 285, 673-679. Venglarik, C. J., Schultz, B. D., Frizzell, R. A., and Bridges, R. J. (1994). ATP alters current fluctuation of cystic fibrosis transmembrane conductance regulator: Evidence for a three state gating mechanism. J . Gen. Physiol. (in press). Wagner. J. A.. Cozens, A. L.. Schulman, H.. Gruenert, D. C., Stryer, L., and Gardner, P. (1991). Activation of chloride channels in normal and cystic fibrosis airway epithelial cells by multifunctional calcium/calmodulin-dependent protein kinase. Narure (London) 349, 793-196. Wangemann, P., Wittner, M., DiStefano, A., Englert. H. C., Lang. H. J., Schlatter, E., and Greger, R. (1986). CI- channel blockers in the thick ascending limb of the loop of Henle. Structure-activity relationship. Pfluegers Arch. 407, S128-Sl41. Welsh, M. J., and Liedtke, C. M. (1986). Chloride and potassium channels in cystic fibrosis airway epithelia. Narure (London)322, 467-470. Welsh. M. J . , Smith, P. L., and Frizzell, R. A. (1982). Chloride secretion by canine tracheal epithelium. 11. The cellular electrical potential profile. J . Membr. Biol. 70, 227-238. Welsh, M. J., Smith, P. L., and Frizzell, R. A. (1983). Chloride secretion by canine tracheal epithelium. 111. Membrane resistances and electromotive forces. J . Membr. Biol. 71, 209-218. Willumsen. N. J.. and Boucher, R. C. (1989). Activation of an apical CI- conductance by Ca” ionophores in cystic fibrosis airway epithelia. A m . J . Physiol. 256, C226-C233. Winding, B., Winding, H.. and Bindslev, N. (1992). Second messengers and ion channel in acetylcholine-induced chloride secretion in hen trachea. Comp. Biochem. Physiol. C 103C(1), 195-205. Wine, J., Bradyen. D. J . , Hagiwara. G., Krouse, M. E., Law, T . C.. Muller, U. J., Solc, C. K.. Ward, C. L.. Widdicombe. J . H.. and Xia. Y. (1991). Cystic fibrosis, the CFTR, and rectifying CI- channels. In “The Identification of the C F Gene: Recent Progress and New Research Strategies” (L.-C. Tsui, G. Romeo, R. Greger, and S . Giorini, eds.), pp. 253-272. Plenum, New York. Worrell, R. T., and Frizzell, R. A. (1991). CaMKII mediates the stimulation of chloride conductance by calcium in T84 cells. Am. J . Physiol. 260, C877-C882. Worrell, R. T.. Butt. A. G.. Cliff, W. H., and Frizzell, R. A. (1989). A volume-sensitive chloride conductance in human colonic cell line T84. A m . J . Physiol. 256, C1 11 1-C1119. Yajima. T., Suzuki, T., and Suzuki. Y. (1988). Synergism between calcium-mediated and cyclic-AMP-mediated activation of chloride secretion in isolated guinea pig distal colon. Jpn. J . Physiol. 38, 427-443. Yang, Y.. Devor, D. C., Engelhardt, J. F., Ernst, S. A.. Strong, T. V . , Collins, F. S., Cohn, J. A., Frizzell, R. A., and Wilson, J. M. (1993). Molecular basis of defective anion transport in L cells expressing recombinant forms of CFTR. Hum. Mol. Genet. 2, 1253- 1261. Zagotta, W. N., Hoshi. T.. and Aldrich, R. W. (1990). Restoration of inactivation in mutants of Shaker potassium channels by a peptide derived from ShB. Science 250, 568-571.
CHAPTER 9
GABA, Receptor-Activated Chloride Channels David R. Burt Department of Pharmacology, University of Maryland School of Medicine. Baltimore, Maryland 21201
1. Introduction 11. Structure of GABAAReceptors A. Relationship to Other Receptors and Ion Channels B. Subunit Multiplicity C. Genes for Subunits D. Alternative Splicing and Diversity E. Post-Translational Modifications F. Composition of Native Receptors G. Protein Chemistry 111. Function of GABAA Receptors A. Electrophysiology of Native and Recombinant Receptors B. Chloride Flux and Binding Measurements C. Desensitization D. Internalization and Clustering IV. Actions of Drugs A. Agonists and Antagonists B. Benzodiazepines and Related Compounds C. Barbiturates D. Steroids E. Other General Anesthetics F. Alcohol G. Calcium. Zinc. Lysine H. Regulation by Chronic Drugs V. Distribution of GABA Receptors A. Central Nervous System B. Peripheral Nervous System C. Glial Cells D. GABA Receptors Outside the Nervous System E. Developmental Changes F. Invertebrate GABA Receptors Current Topics in Membranes, Volume 42
Copyright 0 1994 by Academic Press, Inc. All rights of reproduction in any form reserved.
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David R. Burt
V1. GABA Receptors and Disease A. Epilepsy B. Alcoholism C. Hepatic Encephalopathy D. Other Diseases VII. Comparison with Glycine Receptors VIII. Future Prospects References
1. INTRODUCTION
y-Aminobutyric acid (GABA) is the major inhibitory neurotransmitter in the central nervous system (CNS). GABA is synthesized from glutamic acid, the major excitatory neurotransmitter, by one of two forms of glutamic acid decarboxylase (GAD) (Erlander ef ul., 1991). About 30% of neurons in the brain, particularly small interneurons, are thought to be GABAergic (contain GAD), and most neurons will respond to GABA by reducing their firing rate. The receptors mediating this effect are designated A and B (Bormann, 1988; Sivilotti and Nistri, 1991). GABA, receptors, stimulated by baclofen, have not yet been cloned. They are Gprotein linked, typically decrease calcium or increase potassium conductances, and are not covered in this review. GABAA receptors, blocked by bicuculline, are found on virtually all neurons, both pre- and postsynaptically, and include as part of their structure a chloride channel and binding sites for GABA agonists such as muscimol, for benzodiazepines, barbiturates, and certain steroids, which increase the effectiveness of GABA agonists, and for convulsant compounds such as picrotoxin and t-butylbicyclophosphorothionate(TBPS), which noncompetitively block the chloride channel (Olsen and Venter, 1986; Biggio et ul., 1992; Sieghart, 1992). Much of the interest in GABA, receptors arises from their being the major site of action of the benzodiazepines, a very important class of drugs used as anticonvulsants, sedative-hypnotics, muscle relaxants, and antianxiety agents. Not all chloride channel-linked GABA receptors are modulated by benzodiazepines, however, and not all benzodiazepine effects are GABA related. The structural basis of these observations has become clearer with the cloning of many subunits of the GABAA receptor and the partial delineation of their functional roles. This review emphasizes these recent findings.
9. GABAAReceptor-Activated Cl Channels
217
11. STRUCTURE OF CABA, RECEPTORS A. Relationship to Other Receptors and Ion Channels
GABAA receptors belong to a superfamily of ligand-gated ion channels which includes the closely related glycine receptors, also chloride channels, and more distantly related nicotinic cholinergic receptors and the 5HT, subclass of serotonin (5-hydroxytryptamine) receptors (Schofield et a / . . 1987; Barnard et a/., 1989; Maricq ef a / . , 1991). These latter receptors are cation (largely sodium) channels, as are most of the excitatory amino acid (glutamate and aspartate) receptors, which seem to have the same general subunit structure (four putative transmembrane domains, M 14, starting with a long N-terminal extracellular region and with a long intracellular loop between M3 and M4-see Fig. 1) but show minimal similarity in terms of subunit amino acid sequence (Dingledine et a / . , 1990; Sommer and Seeburg, 1992). The nicotinic and 5HT, subunits show about 15-20% amino acid identity to GABA, receptor subunits (Maricq el al., 1991). Cation vs. anion selectivity seems to depend on a few amino acid differences in the M2 channel domain (Galzi et al., 1992). The similarity of the amino acid sequence of glycine receptor subunits to that of GABAA receptor subunits, about 30%, is almost as great as the similarity ofGABA, receptor subunit families to each other (Betz, 1990). Besides the four transmembrane domains, an area of strong conservation of amino acid sequence among members of the family is a 15-residue Cys-Cys loop in the N-terminal extracellular region, thought to be important in setting up the proper conformation for ligand binding. Kosower (1988) has suggested a less-convincing similarity of GABAAreceptor subunit structure to that of the anion exchange protein (band 3 protein) of erythrocytes. Interestingly, another chloride channel, similar to the voltage-dependent anion channel of mitochondria, seems to copurify with GABAA receptors from brain (Bureau et al., 1992) and may be associated with it in the plasma mernbrane. B. Subunit Multiplicity
The brain possesses a large number of GABAA receptor subunits, at least 17, in five families ( a , - 6 , 71-4, 6, p I - 2 ; see Table I), from which to assemble receptor complexes (Burt and Kamatchi, 1991; Cutting et al., 1992; Harvey e t a / . , 1993).The families are defined by similarity of subunit amino acid sequence, about 70% among family members. As for nicotinic (Galzi et a / . , 1991) and glycine (Langosch e f al., 1988) receptors, the
TESRMHVPGREVHEMSKKGRPPRaR
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205 201 216 213 242
ST.GEYWTTHFHLKRKIGYF TT.W\YPRLSLSFRLKRNIGYF TS.GDYVVnSWFDLSRRMCYF KSAGQFPRLSLHFQLRRNRGW SSTGUYNRLYINFTLRRHIFFF G F L R
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9. GABAA Receptor-Activated C1 Channels
219
subunits are thought to be assembled five at a time to form a ring structure surrounding the central chloride channel (Nayeem et al., 1994), which is lined by the second transmembrane domain of each subunit (Bertrand et al., 1992; Galzi et al., 1992; Xu and Akabas, 1993). As discussed in more detail elsewhere (Burt and Kamatchi, 1991), the possible number of distinct receptors which could be made by different combinations and circular permutations of these known subunits is truly astonishing, numbering in the hundreds of thousands, although the actual number of arrangements formed in viuo probably is fewer than 100. However, the exact subunit composition, stoichiometry, or arrangement still is not known for even 1 native GABAA receptor. Nor is it known how neuron-specific arrangements and, for a given neuron, subtype-specific arrangement(s1 which are presumed to exist are actually achieved. The rules for assembling receptors are only beginning to be worked out; e.g., alpIdual combinations are not formed when a third y 2subunit is also present for incorporation (Angelotti and Macdonald, 1993; Angelotti etal., 1993; Draguhn e t a l . , 1990). Similarly, we have only a hint that subunit composition determines intracellular targeting to different locations (Perez-Velazquez and Angelides, 1993). A simpler situation may occur in fish brain, in which GABAA receptors appear to be homooligomers on protein gels (Deng e f al., 1991). The listing of GABAAreceptor subunits above includes p , and p2 (“rho” from retina, where they are enriched) on the basis of their amino acid sequence similarity to other GABAA receptor subunits and the fact that their functional expression yields GABA-gated chloride channels. Other properties of the expressed receptors are sufficiently unique that these subunits have been suggested to belong to a new class of GABA,receptors (Shimada et al., 1992; Kusama et al., 19931, defined by their insensitivity to blockade by bicuculline and, secondarily, by lack of potentiation by barbiturates o r benzodiazepines. Responses for expressed pl-subunits are still sensitive to blockade by picrotoxin. However, the presumably related responses in Xenopus oocytes injected with retinal poly(A)+ RNA are less sensitive to picrotoxin and TBPS than typical GABAA receptor responses (Woodward et al., 1992, 1993). Additionally, some GABA agonists act FIGURE 1 Conserved structure of GABA, receptor subunits. (Top) Aligned amino acid sequences of one representative of each family (modified from Burt and Kamatchi, 1991). The sequences are from rat, except for p , . which is human. Fully conserved residues are indicated below each row. An overline connects two Cys residues thought to form a disulfide bond important in shaping the ligand binding domain. The putative transmembrane domains (M1-M4) are boxed. The eight heavy bars above the sequences show the approximate locations of introns in the coding sequences, for subunits where these are known. (Inset) Illustration of transmembrane topology of each subunit.
220
David R. Burt TABLE I Vertebrate GABA, Receptor Subunits" Amino acids Sites Message ( + signal) for size in in rat N-CHO kilobases
Protein size in kilodaltons
Comments
a: Affect benzodiazepine (BZD) pharmacology, affinity for GABA
ffl
428 ( + 27)
2
%
423 ( + 28)
3
ff3
ff4
a5
ff6
PI P2 P3.3a
P4 P4'
YI Y2s
Y2L
Y3
Y4
4.2,3.8
50. 51
Most abundant; gives type I BZD pharmacology; HCL = 5q3 1 . I -
q33.2
Type I1 BZD pharmacology: HCL = 4~12~13 465 ( + 28) 4 4.2 56.59 & 61 Type I1 BZD pharmacology: HCL = Xq28 533 ( + 19) 3 4.0(bov.) >65 Largest subunit: pharmacology like a6 433 (+3l) 4 2.8 53.57 Gives unusual type 11 BZD pharmacology (has been termed ( ~ 4 ) : HCL = 15qllq13 434 ( + 19) 3 1.8,2.5 56,57 Found only in cerebellar granule cells: selective for Ro 15-4513 P: Needed for efficient assembly; contain conserved protein kinase A sites 449 ( + 25) 3 12 52? Less abundant than Pz and P3: HCL = 4~12~13 450 ( + 24) 3 8 55? Probably most abundant P ; HCL = 6 448 ( + 25) 3 6.0,2.5 54? HCL = I5qllql3,near AngelmadPrader-Willi locus; 5' end alternative splicing 459 ( + 25) 4 Alternative splicing by use of two splice donor sites. (Not in mammals?) 463 by alt. spl. (chick) y : Enable benzodiazepine binding, zinc insensitivity 3 3.8 Found in glia; gives atypical BZD 430 ( + 35) response. HCL = 4p14-q21.1 428 ( + 38) 3 4.2.2.8 43-49 Gives typical BZD response: alternative splicing (miniexon) gives new protein kinase C site; HCL = 5q31.1-q33.2 436 via alternative splicing 450 ( + 17) Gives typical BZD response, with 2 some differences from y z 436 (+21) 3 5.8 Not in mammals? (chick)
3.6.6.6
52. 53
221
9. GABAA Receptor-ActivatedCl Channels TABLE I Continued
Amino acids Sites Message size in ( + signal) for in rat N-CHO kilobases 6
433 ( + 1 6 )
p
458 ( + I S ) 445 ( + 2 0 )
p2
Protein size in kilodaltons
Comments
6: Functional role unknown 2 2.0, 3.0 54 HCL = 1 (short arm) p: Give very atypical pharmacology (GABAc?) 3 3.9 (bov.) High in retina; HCI = 6q14q21 2 HCL = 6q14q21
(' Sites for N-CHO are number of amino-terminal extracellular consensus sequences (Am-X-Ser/Thr) for N-linked glycosylation. Subunit protein sizes are apparent sizes on denaturing gels except ad,for which the theoretical size without glycosylation is given. Under Comments, BZD is benzodiazepine and HCL is human chromosomal locus. Most data are for rat. but data on p4and y4 are for chicken and data on pI and p? are for human. Selected references on each subunit are as follows: aI(Schofield et a / , , 1987: Buckle et a / . . 1989; Malherbe et a/.. 1990a; Buchstaller et a / . . 1991b: Keir er a/., 1991: Wang et a/.. 1992a: Wilcox et a/., 1992); a? (Levitan P t a/.. 1988; Buckle e t a l . , 1989: Khrestchatisky et al., 1991: Wang ct a/.. 1992a): a, (Levitan et a/.. 1988: Buckle et a/.. 1989: Malherbe e t a / . . 1990~:Wang et a/., 1992a); a4 (Ymer et a / . , 1989a: Wisden et a/.. 1991): a( (Khrestchatisky ef a/., 1989: Mahlerbe e f a/.. 1990~:Pritchett and Seeburg. 1990: Knoll er a/., 1993; Sieghart P I a/.. 1993): a, (Liiddens et al., 1990: Kato. 1990);PI (Schofield ef a/., 1987: Buckle er a/., 1989: Malherbe et a/.. 1990a: Kirkness et a/., 1991): & (Ymer era/.. 1989b: Buchstalleretal.. 1991a: Hadinghamera/.. 1993):p,(Ymerera/.. 1989b: Wagstaff rt a/.. 1991a, b: Kirkness and Frazer. 1993): p4(Bateson e t a / . . 1991: Lasham e f a/.. 1991); yI (Ymer er c d . , 1990: Wilcox et a!.. 1992): yZs(Pritchett et a/.. I989b: Shivers et a/.. 1989: Malherbe et 01.. 1990b; ~ et a / . , 1990: Kofuji et a/., 1991): y, (Wilson-Shaw Benke ef a/., 1991a: Wilcox et a/.. 1992): y 2 (Whiting er < I / . . 1991: Knoflach et a/.. 1991: Herb e t a l . . 1992): y4 (Harvey e t a / . , 1993): 6 (Shivers et al., 1989: Sommer e f a/.. 1990: Zhao and Joho. 1990: Benke et 01.. 1991b: Wang et al., 1992b); pI (Cutting er al.. 1991.1992: Shimada et a/.. 1992); and p z (Cutting et a/.. 1992: Kusama e r a / . , 1993).
as antagonists. Similar responses have been described in perch retina horizontal cells (Qian and Dowling, 1993)and rat bipolar cells (Feigenspan et al., 1993). C. Genes for Subunits
A major goal in cloning genes for the different subunits is to discover the upstream control elements for subunit message transcription that permit expression in individual neurons of the appropriate combinations of subunits. An unrelated goal is to attempt to map the subunit genes on the chromosome and find if any map to the same locus as known genetic diseases. The former approach has yet to yield much illumination (see, e.g., Sommer et al., 1990; Kirkness and Fraser, 1993), but the latter approach, when applied to the human &subunit gene, yielded an apparent match with the AngelmadPrader-Willi region on chromosome 15 (Wagstaff et al., 1991b; Saitoh et al., 1992). The cq gene is just distal, within 100 kbp (Knoll et al., 1993). Identified loci of other subunits are listed in
222
David R. Burt
Table I. Some other subunit genes appear to be clustered, e.g., a Iand y 2 on chromosome 5 (Wilcox et al., 1992);cq,0,. and yI on chromosome 4 (Wilcox et al., 1992); and p I and pz on chromosome 6 (Cutting et al., 1992; also contains p2, Hadingham et al., 1993), of unknown significance. A direct role of the p, gene in Angelman’s syndrome appears to have been eliminated by an affected patient in which both parental alleles are still present (Reis et al., 1993), but in mice it maps to a cleft palate locus (Culiat et al., 19931, suggesting a role in facial development. The subunit genes which have been reported thus far have a very similar organization of 9 or 10 exons, with a highly conserved location, if not size, of introns among subunits and species (Fig. 1). The size of these genes varies from only 13 kb for the mouse S gene (Sommer et al., 1990) to more than 65 kb for the human p, gene (Kirkness et al., 1991) and the chicken p4gene (Lasham et al., 1991). The exon numbers or boundaries are not well conserved with nicotinic receptor subunit genes. D. Alternative Splicing and Diversity The potential multiplicity of GABA, receptors which could be formed from combination of 16 or more different gene products would appear to be more than sufficient without any additional means of generating diversity, but such means do exist in the form of alternative splicing of RNA transcripts and post-translational modification of the subunit proteins. Alternative splicing has been demonstrated for the y2-subunit(Whiting et al., 1990; Kofuji et al., 1991), where it arises from incorporation of a small exon of only 24 bases; for the &subunit in chickens (Bateson et al., 1991), where it arises from alternative splice donor site selection to add only 12 bases; for the p2 subunit in chickens, where it arises by inclusion of a 51 base exon (Harvey et al., 1994) and for the &-subunit (Kirkness and Fraser, 1993), where an alternative upstream exon la for 5’-untranslated and signal sequences is used rarely to give a protein product which barely differs from the major &-subunit. In the first three cases, alternative splicing occurs in the putative intracellular loop between the third and fourth transmembrane domains (M3 and M4). For the y,-subunit, alternative splicing creates a new site for phosphorylation by protein kinase C (Whiting et al., 1990; Moss ef al., 1992a), and this has an important influence on whether GABA responses from expressed receptors containing the subunit are potentiated by ethanol (Wafford er al., 1991; Wafford and Whiting, 1992; but see Sigel et al., 1993). The y 2 alternative splicing is regionally and developmentally regulated in several species (Whiting et al., 1990; Wang and Burt, 1991; Zahniser et al., 1992); the anterior pituitary gland expresses only the short form (Valerio et al., 1992). The & alternative splicing is also regionally and developmentally
9. GABAA Receptor-ActivatedC1 Channels
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regulated (Kirkness and Fraser, 1993). Multiple protein bands with subunit-specific antibodies after N-deglycosylation have suggested possible additional alternative splicing of the a*-and cq-subunits (Buchstaller et al., 1991b) and pz- and p3 (beyond that known)-subunits (Buchstaller et al., 1991a; Pollard et al., 1991). Extensive alternative splicing, in two regions of the extracellular domain, also exists for the Drosophila Rdl GABAA receptor gene associated with cyclodiene resistance (ffrenchConstant and Rocheleau, 1993). E. Post- Translational Modifications
Post-translational modification, if cell-type specific, could help generate diversity of GABA, receptors. Apparent regional differences in effects of enzymatic carbohydrate removal on benzodiazepine binding have been reported (Sweetnam and Tallman, 1986), but this may reflect regional differences in subunit composition. More definitive is evidence for differential O-glycosylation of the as-subunit (Sieghart et al., 1993). In Xenopus oocytes, inhibition of N-linked glycosylation by tunicamycin reduces expression of GABA, receptors (Sumikawa et al., 1988), and site-directed mutagenesis of a,-subunit glycosylation sites in 293 cells has a similar effect (Hastings et al., 1992). In several other receptors, N-linked glycosylation seems to be necessary for receptors to attain an active conformation (e.g., possible guidance of subunit assembly and membrane trafficking), but is not required for maintenance of ligand binding activity (Olson and Lane, 1989). Phosphorylation is an important means of modulating receptor function for ligand-gated ion channels (Swope et al., 1992), including natural GABAA receptors (e.g., Porter et al., 1990). It probably varies as much with time and circumstance as with cell type. Various GABAA receptor subunits contain potential sites for phosphorylation by protein kinases A (PKA) and C (PKC) and protein tyrosine kinases (Leidenheimer et al., 1991). For some residues, e.g., Ser-409 of p, for PKA, Ser-410 of p2 for PKA and PKC, Ser-327 of y2s and Ser-343 of yZLfor PKC, this phosphorylation appears to influence desensitization and other aspects of receptor function (Leidenheimer er al., 1992; Moss et al., 1992a,b;Kellenberger et al., 1992; Waf€ord and Whiting, 1992).Ser-343ofy,, is not necessary for the PKCmediated enhancement of diazepam responses (Leidenheimer et al., 1993).
F, Composition ofNative Receptors Evidence on the composition of native GABAA receptors is beginning to accumulate from isolation of receptors from different brain regions with subunit-specific antibodies, seeing what other subunits come along. These
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conclusions can be checked against data on the differential distribution among brain regions of subunits (e.g., from in situ hybridization of mRNAs or immunohistochemistry of proteins), seeing which ones seem to occur together, and on the functionality of artificial combinations of cloned subunits expressed in Xenopus oocytes or cell lines. It now appears that most receptors in the brain contain one or more a-subunits, one or more p-subunits, and usually a y- and/or &subunit. The most common combination may be a I - p 2 - y 2 (Benke et al., 1991a; Fritschy et al., 1992; Laurie et al., 1992a; Persohn et al., 1992; Wisden et al., 1992). The subunit composition of a GABAAreceptor subtype would be easiest to determine for a cell line expressing only that subtype. Descriptions of cell lines expressing complete, functional GABAA receptors have been late to appear (e.g., for anamolous, partial receptors, Kasckow et al., 1992; Kirkness and Fraser, 1993; Rohde and Harris, 1992) but there are now a few. These include IMR-32 human neuroblastoma cells (Anderson et al., 1993), available from the American Type Culture Collection, and immortalized hypothalamic GTI-7 cells (Hales et al., 1992), designed for expression of gonadotropin-releasing hormone. In both cases, the lack of a benzodiazepine response has suggested the absence of a y2-subunit. By use of the polymerase chain reaction (PCR), GT1-7 cells contained a I , p i , and @,-subunitmRNAs, but not az,as,a6,pZ,y 2 ,or &subunit mRNAs (Hales et al., 1992). It is unclear whether the apparent p-subunit multiplicity in the cell line implies receptor subtype heterogeneity, or whether both PI- and &-subunits may be contained in the same receptor molecules. C. Protein Chemistry
Studies of the GABAA receptor as a protein have included binding studies, photoaffinity labeling, detergent solubilization, benzodiazepine affinity purification, examination of subunit bands on denaturing gels (SDS-PAGE), and use of monoclonal and polyclonal antibodies against either native receptors or subunit-specific peptides synthesized from sequence knowledge obtained by cloning (Stephenson, 1988; Olsen and Tobin, 1990; DeLorey and Olsen, 1992). Binding studies have employed ligands directed against 3 main loci on the receptor complex: the ligandbinding site (e.g., agonists GABA, muscimol; antagonists bicuculline, gabazine), the benzodiazepine site (e.g., agonists diazepam, flunitrazepam; antagonist flumazenil), or the chloride channel (e.g., TBPS). Flunitrazepam itself is suitable as a photoaffinity label and appears to label primarily a-subunits. GABAAreceptors purified from brain by steps which include detergent solubilization and use of a benzodiazepine affinity col-
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umn are glycoproteins of ca. 230 kDa that retain the binding properties of membrane-associated receptors. Although they were originally thought to be composed of two a-subunits of ca. 53 kDa and two @-subunitsof ca. 57 kDa (Stephenson, 1988), recent cloning of subunits has changed the picture of receptor composition from four to five subunits, as described above. More refined protein chemistry has revealed the existence of multiple a- and p-subunit isoforms, which have mostly been identified with specific cDNAs using selective antibodies (e.g., Buchstaller et al., 199la,b-see Table I). One of the most productive lines of investigation at present, noted above, employs subunit-specific antibodies to isolate native receptors from various brain regions by immunoprecipitation or immunoaffinity chromatography and seeing what other subunits are also found in the resulting pellets or fractions. The most abundant subunit, as judged from immunoprecipitation, is a I (40% or more of detergent-solubilized receptor binding from whole rat brain, size 50-51 kDa, e.g., McKernan et al., 1991b). There appear to be minor populations of receptors containing a,-subunits in combination with az-, a,-, and a,-subunits (Duggan et al., 1991; Endo and Olsen, 1993; Liiddens et al., 1991; Pollard et ul., 1993; Zezula and Sieghart, 1991). Both a? (28%, 53 kDa)- and aj (24%, 59 and 61 kDa)subunits immunoprecipitate substantial but much lower proportions of receptor binding, while other a-subunits are more minor still (McKernan et al., 1991b). Two nonselective antibodies against @-subunits recognize bands at 57, 54, 53, and 5 2 kDa in rat brain (Endo and Olsen, 1992), but these bands are not clearly assigned to cloned sequences. One of these, against a protein kinase domain in the M3-M4 intracellular loop, immunoprecipitates 75% of solubilized [3H]muscimolbinding from whole rat brain. As already noted, earlier studies had seen multiple bands for both p2- and @,-subunits (Buchstaller etal., 1991a; Pollard et ul., 1991). Immunoprecipitation with antibodies directed against the N-terminus of the y2-subunit brings down about 50% (Benke et al., 1991a) or 75% (Duggan et al., 1992) of solubilized, affinity-purified benzodiazepine binding in rat or bovine brain regions, at an apparent size of 43-49 kDa. Muscimol binding is precipitated in parallel, and a relatively high proportion of receptors (>20%) appear to contain a I - .&-, and y2-subunits in common (Benke et ul., 1991a; Khan et nl., 1993). Immunoprecipitation with antisera against peptides contained in the 6-subunit brings down about 20% (just solubilized) or 30% (also affinity purified) of flumazenil binding, at an apparent size of 54 kDa (Benke et ul., 1991b). This had suggested coexistence of the &subunit and a y-subunit in some receptors, since benzodiazepine binding requires a y-subunit (see below). This has been confirmed by immunoaffinity chromatography for yz (Mertens et al., 1993). Such 6 and
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y2 coexistence is not supported by mRNA distribution data (Laurie et al.,
1992a; Wisden et al., 1992). 111. FUNCTION OF GABAA RECEPTORS A, Electrophysiology of Native and Recombinant Receptors
Electrophysiological studies of GABAA receptors have moved from voltage-clamp and fluctuation analysis of native receptor populations to patch-clamp studies of individual channels of known subunit composition-if not yet exact arrangement or stoichiometry. The usual response to channel opening is a net inward flux of negative chloride ions (outward current), hyperpolarizing the neuronal membrane and driving it away from firing threshold. Native GABAA receptors exhibit multiple conductance levels, complex kinetics of activation, with apparent positive cooperativity for agonist and a degree of voltage dependence, and multiple phases of desensitization (Bormann, 1988). Many of these properties vary with source of receptors. They are mimicked to varying extents by recombinant receptors of different subunit compositions (Mathers, 199 1) and are shared by other ligand-gated ion channels. Two systems have been used to date for most studies of the expression of recombinant GABAA receptors: injection of RNA transcribed in uitro into Xenopus oocytes (Sigel, 1990) and transient transfection of cDNAs into human embryonic kidney 293 cells (Pritchett et al., 1988). A few studies have used stable transfection (e.g., Im et al., 1992; Moss et al., 1990; Petke et al., 1992; Wong et al., 1992). The oocyte system has also been widely used for expression of native mRNAs for GABAA receptors, often in conjunction with other methods, such as selective breeding (Wafford et al., 1990), hybrid arrest (Wafford er al., 19911, and careful selection of message according to source and size (Woodward er al., 1992). For some glutamate receptor subunits, it has been shown that the transfection of two together into a cell line leads to the formation of homomeric and heteromeric channels simultaneously (Burnashev et al., 1992), illustrating one of the difficulties of interpretation of all of these methods. Others include possible variations in lipid environment and post-translational processing and incorporation of endogenous proteins (Buller and White, 1990). Expression of cloned GABAA receptor subunit cDNAs in oocytes (Blair et al., 1988) or 293 cells (Pritchett et al., 1988) indicates that single subunits poorly but detectably express many properties of GABAAreceptors. (An exception is the p,-subunit, which gives robust expression; Shimada et al., 1992.) Various a-/3pairs do so quite well, but without benzodiazepine modulation (Levitan et al., 1988); a-y pairs and 0-7 pairs, in declining
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order, are less successful (Verdoorn et al., 1990; but see Wong e t a / . , 1992, whose results may have been influenced by endogenous fi3 expression in HEK 293 cells; Kirkness and Fraser, 1993). The best approach to native receptor function is obtained with various a-fi-y combinations. In these combinations, a y-subunit seems to be required for benzodiazepine modulation of the GABA response (Pritchett et al., 1989b; Ymer et al., 1990; Moss et al., 1991; Puia et al., 1991). As well as conferring sensitivity to modulation by benodiazepines, the y,-subunit seems to confer sensitivity to potentiation by lanthanum ions (Im et al., 1992) and insensitivity to inhibition by zinc (Draguhn e t a / . , 1990; Smart et al., 1991). Many aspects of benzodiazepine pharmacology are determined by differences between the various a-subunits (Pritchett er ai., 1989a; Pritchett and Seeburg, 1990; Luddens et al., 1990), which also affect GABA affinity (Levitan et al., 1988). Site-directed mutagenesis has localized some a-subunit differences in functionality to single amino acid residues: Gly at a I 200 for type I pharmacology (Pritchett and Seeburg, 1991), His at at 101 for benzodiazepine agonist and antagonist binding (Wieland et al., 1992). The most complete study to date of the functional properties of various subunit combinations (Sigel et al., 1990) was flawed by the inadvertent use of a mutant a I clone (Sigel et al., 1992), with a Leu substituted for a conserved Phe at residue 64. This resulted in a ca. 200-fold drop in apparent affinities for agonist GABA and antagonist bicuculline and aloss of positive cooperativity of GABA gating. Site-directed mutations in homologous sites in fi,- and y,-subunits resulted in only intermediate and small drops in GABA affinity, respectively, and no change in cooperativity or antagonist affinity (Sigel et al., 1992). These results suggest an importance of asubunits in binding of agonists and antagonists as well as of benzodiazepines. Combinations giving atypical functionality include those containing a4 and a6,which lack classical benzodiazepine agonist binding (Luddens er al., 1990; Wisden et al., 1991), and y I , which may yield apparent agonist activity of benzodiazepine inverse agonists (von Blankenfeld et a f . , 1990; Puia et al., 1991). y3-containing combinations have selectively reduced benzodiazepine agonist affinity (Herb et al., 1992). As already noted, some combinations containing p,-subunits are so atypical as to have been termed GABA, receptors (Shimada et al., 1992). As a channel, the GABAAreceptor appears to have two sites that bind chloride and a single file transport mechanism (Bormann et al., 1987). The major observed conductance state of native receptors varies with neuron type, being about 28-30 pS in spinal cord, with others at about 12, 19, and 44 pS (Bormann et a/., 1987). By contrast, the main conductance state in hippocampus has generally been 20 pS or less (e.g., Allen and Albuquerque, 1987). In recombinant receptors, the presence of a
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y2-subunit seems to help confer a higher (32 pS) main single-channel conductance (Verdoorn et a / . , 1990). In general, drugs appear to affect channel kinetics rather than channel conductances, and membrane depolarization increases probability of channel opening. Complex gating schemes for native receptors have been proposed in which a single GABA molecule is permitted to gate a short-lived open state, but entry into other, longer-duration open states requires binding of two GABA molecules (Macdonald et al., 1989a; Weiss and Magleby, 1989). It is likely that many drugs preferentially bind to one or another conformational state as part of their mechanism (e.g., barbiturates, Macdonald et al., 1989b). Although most responses to GABA, receptor stimulation involve neuronal hyperpolarization and inhibition, a number of workers have observed apparent depolarizing responses mediated by GABA, receptors. Sites include hippocampal pyramidal cell dendrites (e.g., Alger and Nicoll, 1982) and hippocampal interneurons (Michelson and Wong, 1991). In the latter site, depolarization is sensitive to blockade by picrotoxin and bicuculline and appears to be due to the responsive cells possessing higher than usual levels of intracellular chloride. A similar explanation for dendritic depolarization (e.g., Avoli, 19921, involving maintenance of intracellular chloride gradients, is harder to accept. Receptor heterogeneity, with the dendritic receptor also gating another ion, such as bicarbonate, is another possibility (Lambert et a / . , 1991). Bicarbonate’s role is not well supported by recent data (Grover et al., 1993), but the general idea is supported by differential immunofluorescent staining for a,- and a,-subunits between soma and dendrites of cerebellar Purkinje cells and hippocampal pyramidal cells (Fritschy et al., 1992). There is still no evidence for differential ion selectivity of receptors made from these subunits, however.
B. Chloride Flux and Binding Measurements Radioactive chloride flux measurements have been widely used in an attempt to replicate biochemically the chloride current measurements of electrophysiology, only with much more limited time resolution. Although the method has been applied successfully in cultured neurons and brain slices, the most usual preparation is closed membrane vesicles (“synaptoneurosomes” or “microsacs”) which include postsynaptic regions (Harris and Allan, 1985; Schwartz et a / . , 1986). Besides the usual problems with biochemical measurements (tissue heterogeneity, endogenous GABA, and other substances, e t c . ) , the long haIf-life of ’ T 1 (310,000 years) leads to low specific activity and high expense. Another way to measure chloride flux is by means of newer chloride-sensitive fluorescent indicators. Only
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limited use to date has been made of these methods for GABA, receptors (Anderson et al., 1993; Engblom et nl., 1991; Wong et al., 1992) and the similar glycine receptors (Garcia-Calvo et al., 1992). Binding measurements yield only an indirect index of function, through modulation of binding of one ligand (typically muscimol, flunitrazepam, or TBPS) in the presence of a drug of another type. Thus the “GABA shift” consists of the increased affinity of binding of benzodiazepines in the presence of GABA (Tallman et nl., 1978) and vice versa. These measurements can be used to predict potencies of GABA agonists or of benzodiazepines as modulators of GABA, receptors. Similarly, the displacement of [35S]TBPSbinding in the presence of GABA can be used to screen for modulators (e.g.. Im and Blakeman, 1991).
C. Desensitization An important phenomenon, which seems to be intrinsic to any functional combination of GABAA receptor subunits, is desensitization in response to prolonged (a few seconds) application of higher concentrations (ca. 10 pM and above) of GABA, with recovery over a few minutes. This is hard to avoid in measurements by chloride flux (Kardos and Cash, 1990). Continued application of GABA to receptors on intact cells produces a decrease in the GABA-gated current for two reasons: a decrease in the transmembrane chloride gradient and desensitization of the receptors (Huguenard and Alger, 1986). The molecular mechanisms of desensitization of GABA, receptors still are poorly understood, but desensitization is presumed to represent one or more conformational states of the receptor complex, resulting in bursts of channel opening alternating with longer silent periods (Palotta, 1991). Its speed, extent, and other properties vary with source and type of cells, age in culture, etc., or, in transfected cells, with the subunit composition (e.g., slowed by y2-subunit; Verdoorn et al., 1990; Moss et al., 1992b). Among the properties which have been reported for desensitization in cultured hippocampal (Oh and Dichter, 1992) and cortical (Frosch et al., 1992) neurons are independence of the charge transferred or current induced by a given concentration of GABA, but dependence on receptor activation (preexposure to low GABA concentrations does not affect response to high concentration); marked voltage dependence (slower and less extensive at depolarized potentials, almost absent at + 30 mV) in whole cells, but not isolated membrane patches; and greater speed in isolated patches. Voltage dependence of desensitization is not seen in cultured retinal ganglion cells (Tauc et al., 1988). Desensitization can be influenced by GABAA receptor phosphorylation state, e.g., being slowed in a,@!combinations by @,-subunitphosphorylation at Ser4w
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by CAMP-dependent protein kinase (Moss er al., 1992b). In neuronal nicotinic receptors (a,-subunit homooligomers), mutation of a conserved Leu (247) to Thr in the M2 channel domain appears to convert a desensitized state to a conducting state (Bertrand er al., 1992). Change of Val (251) to Thr has a similar effect (Galzi et al., 1992). Mutation of the equivalent residues have not yet been reported in GABAA receptor subunits. D. Internalization and Clustering
A phenomenon which may be related to desensitization, only requiring longer periods of time, is agonist-induced downregulation, generally involving internalization followed by sequestration or proteolysis of receptors. Downregulation of GABA, receptors has been demonstrated in tissue culture (e.g., Roca er al., 1990a), with a half-time of about 25 hr. Internalization of GABAAreceptors has also been described (Tehrani and Barnes, 1991), based on an indirect approach using an impermeant benzodiazepine ligand and detergent permeabilization. In cultured chick cortical neurons, about 7% of benzodiazepine binding sites appeared to be intracellular, but this proportion was increased to 18% by exposure to 1 mM GABA for only 4 hr. Many intracellular receptors in the absence of agonist are presumably on their way out (after synthesis) rather than on their way in (internalized) (reviewed in Hopkins, 1992). These proportions of intracelMar GABA receptors were somewhat lower than those (about 20%) reported earlier by another group using a similar approach without agonist (Czajkowski and Farb, 1989). This same group found the disappearance of photoaffinity-labeled receptors in cultured chick brain to occur in two phases, with half-lives of about 4 hr (42% of receptors) and 32 hr; following photoinactivation, receptor reappearance was complete in 24 hr (Borden and Farb, 1988). In rat brain, a class of GABAAreceptors with low affinity for flunitrazepam is associated with clathrin-coated, presumably endocytotic vesicles (Tehrani and Barnes, 1993). In a related observation at the message level, 48-hr exposure of cultured chick neurons to 1 mM GABA has been shown to decrease mRNA levels for a,- and a2-subunits by more than 50% (Montpied er af., 1991a), presumably due to effects on message transcription or stability. In other systems, agonist-induced internalization is generally preceded by clustering of receptors on the cell surface. Interestingly, the normal state of GABA, receptors appears to be in clusters, at least in some cultured neurons, as revealed by antibodies (Ventimiglia er al., 1990) or patch-clamp recording (Frosch and Dichter, 1992). The latter study demonstrated that this was true whether the neurons are innervated or not. The relationship of these clusters to synapses or synapse formation
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is still unknown. “Hot spots” have been seen in sections of mature brain (Fritschy et al., 1992), often in association with synapses, and have also been visualized on cerebellar granule cells by freeze-fracture electron microscopy (Caruncho er a!., 1993). This has been an area of intense study for nicotinic cholinergic receptors at the neuromuscular junction (Froehner, 1991), and many of the mechanisms of clustering probably are similar for GABA, receptors. Cytoskeletal attachment appears to influence pharmacology of glycine receptors (Takagi et al., 1992).
N. ACTIONS OF DRUGS A. Agonists and Antagonists
Besides GABA, direct agonists of GABA, receptors include muscimol, 3-aminopropanesulfonic acid (3-APS), piperidine-4-sulfonic acid, 4,5,6,7tetrahydroisoxazolo[5,4-c]pyridin-3-ol(THIP), isoguvacine, and isonipecotic acid (Kerr and Ong, 1992).The subject of extensive structure-activity studies, they can be of potency equal to or greater than that of GABA for various responses, and many have been tried as binding ligands (Olsen and Venter, 1986). As noted above, binding of two agonist molecules appears to be needed for efficient gating of native receptors (but not all recombinant ones; Mathers, 1991), and it still is not clear which subunits preferentially bind agonists. Site-directed mutagenesis has suggested importance of both p (Amin and Weiss, 1993) and a (Sigel et al., 1992) subunits. The classical competitive antagonist of the GABA recognition site is the alkaloid bicuculline. Newer antagonists include gabazine (SR-95531, 2-[3-carboxypropyl]-3-amino-6-p-methoxyphenylpyridaziniumbromide), pitrazepine, securinine, and the steroid RU5135 (Kerr and Ong, 1992; Rognan et al., 1992).D-Tubocurarine, a classical nicotinic antagonist, also can act at the same site. Except for RU5135 (which acts at glycine receptors also), these drugs are not very potent. Another class of antagonist is noncompetitive “chloride channel blockers,” prominently including the alkaloid picrotoxin (active component picrotoxinin) and synthetic cage convulsants such as TBPS as well as, surprisingly, penicillin G. These exhibit use-dependent blockade, stabilizing closed forms of the C1- channel, and decreasing probability of channel opening (e.g., Newland and Cull-Candy, 1992; Woodward et al., 1992). Many other drugs also appear to act at the picrotoxin site, including the convulsant pentylenetetrazol (De Deyn and Macdonald, 1989) and ybutyrolactones (Holland et al., 1991), which include “inverse agonists” (relative to picrotoxin, i.e., augment GABA function) as well as “agonists” (like picrotoxin) and “antagonists” (block C1- channel blockade
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by picrotoxin). This site may also be a target for certain endogenous steroids. B. Benzodiazepines and Related Compounds
As already noted, the most important class of drugs acting on GABAA receptors is the benzodiazepines. An example is diazepam (Valium). They increase frequency of channel opening as well as cause a modest increase in channel mean open time (Study and Barker, 1981).The complex developments in this area introduced a new term into pharmacology, “inverse agonist,” to describe drugs which have an effect on GABAA receptors opposite from that of conventional benzodiazepines (agonists), which increase the probability of channel opening. An example of such drugs, which are better termed negative allosteric effectors, is the p-carboline DMCM (methyl-6,7-dimethoxyl-4-ethyl-~-carboline-3-carboxylate). They are anxiogenic and proconvulsant. There are also conventional antagonists, such as flumazenil (Ro 15-1788,ethyl-8-fluoro-5,6-dihydro-5-methyl6-0x0-4H-imidaza [I ,S-a] [ 1,4]benzodiazepine-3-carboxylate), which prevent the actions of both positive and negative allosteric effectors. Partial agonists, such as clonazepam, bretazenil, divaplon, and abecarnil, with high affinity but low efficacy, have generated the most recent interest as optimal therapeutic agents for anxiety and panic reactions with low incidence of side effects such as sedation, ataxia, or tolerance (Haefely et al., 1990; Scaf, 1991; Puia et al., 1992). The benzodiazepine binding site accomodates a variety of drugs of diverse structure, making the subject, which is full of arbitrary drug company designations and obscure abbreviations, too complex for more than a brief consideration here (see Gardner et al., 1993, for a more complete review). Benzodiazepine receptors have been divided into two classes, type I and type 11, based on their affinity for the triazolopyridazine CL 218,872 (I, high affinity), and the type I pharmacology is associated with the presence of the a,-subunit (Pritchett et al., 1989a; Zezula and Sieghart, 1991). Another drug, the imidazopyridine zolpidem, further subdivides the type I1 receptors, giving intermediate affinity for combinations containing a2-and a,-subunits and very low affinity for those containing a5subunits (Pritchett and Seeburg, 1990; Puia et al., 1991). Similarly, the partial inverse agonist (and behavioral alcohol antagonist) Ro 15-4513 (sapmazenil) binds with high affinity only to subunit combinations containing a4 (Wisden et a/., 1991)- and a6 (Luddens et af., 1990)-subunits, from which it cannot be competed by typical benzodiazepine agonists. The requirement for y-subunits, generally y 2 , for any of these effects has already been described. Imidazoquinoxalines (Petke et al., 1992) are
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another class of drugs, not already mentioned, which interact with benzodiazepine receptors. They include both agonists (U-79098)and antagonists (U-78875). The actions of benzodiazepines are of such high affinity and specificity, paralleling observations for opiates, that the discovery of endogenous opioids soon led to the search for endogenous benzodiazepines. Initial interest centered on purines such as inosine, but more recent attention has turned to polypeptides such as diazepam binding inhibitor (DBI), p-carbolines such as ethyl-p-carboline-3-carboxylate(P-CCE), originally extracted from human urine (and formed by cyclization of tryptophan), actual benzodiazepines (perhaps from diet), and “endozepines” with presumably related but undetermined structures (Rothstein et al., 1992).DBI, containing 86 amino acids, is a flumazenil-sensitive, negative allosteric modulator at GABAA receptors (Costa and Guidotti, 1991), as are several smaller peptides derived from it [e.g., octadecaneuropeptide (ODN), DBI:33-50 and triakontatetraneuropeptide (TTN), DBI: 17-50]. The pcarbolines include positive as well as negative allosteric effectors; e.g., abecarnil is anxiolytic. The functional significance of any of these compounds remains to be established. The above discussion has ignored another whole class of benzodiazepine receptors, the peripheral benzodiazepine receptors, which are associated with mitochondria (Gavish et al., 1992; McEnery et al., 1992; Parola et al., 1993) and have a distinct pharmacology, including affinity for DBI. Effects include modulation of steroid biosynthesis (Cavallaro et al., 1992; Krueger and Papadopoulos, 1992), making an interesting connection with the effects of steroids on GABA, receptors (see below). Some benzodiazepine effects in uiuo could be related to interactions with still other receptors, e.g., for adenosine (Phillis and O’Regan, 1988) or thyrotropinreleasing hormone (Sharif and Burt, 1984).
C. Barbiturates Barbiturates are important general anesthetics, sedatives, and hypnotic drugs, although much less so than before the discovery of benzodiazepines and other newer, safer drugs. One of them, phenobarbital, still is an important anticonvulsant. There are not thought to be any endogenous barbiturates, a blessing, although endogenous steroids described in the next section may amount to the same thing. Barbiturates stabilize GABAA receptors in the open and conducting configuration (Study and Barker, 1981), at the single-channel level prolonging burst duration by favoring longer-lived open states (Macdonald et al., 1989b), and also are capable of opening these channels by themselves at higher concentrations. The
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latter activity is more characteristic of pentobarbital, used as a general anesthetic, than of phenobarbital, useful in epilepsy, and depends on different structural determinants than GABA agonist activation (Amin and Weiss, 1993). Barbiturates seem to be active on virtually any subunit combination, with the exception of p , homooligomers (Shimada et a l . , 1992), as already mentioned. D. Steroids
Certain endogenous steroids such as progesterone, deoxycorticosterone, and some of their metabolites produce barbiturate-like effects on GABAAreceptors of the central nervous system at concentrations similar to those found in the brain (reviewed in Majewska, 1992; Paul and Purdy, 1992). This mechanism is distinct from the usual steroid actions in the nucleus (McEwen, 199 1). So-called neurosteroids, which include pregnenolone, dehydroepiandrosterone, and their sulfates and fatty acid esters, seem to be synthesized de nouo in the brain, primarily in glia (oligodendrocytes). Some steroids, like some barbiturates, have been used as anesthetics (e.g., alphaxalone). In uiuo, these steroids may contribute to known influences of stress or reproductive status on behavior, e.g., seizure threshold (Wilson, 1992). The most potent steroid activator of GABAA receptors (nM potency) is 5a-pregnane-3a-ol-20-one(tetrahydroprogesterone, allopregnanolone), which increases in response to stress (Purdy et al., 1991). Steroids resemble barbiturates in acting from outside the cell, in being insensitive to flumazenil, in prolonging GABA-induced chloride conductance (burst duration) of GABAA receptors, and in opening channels alone in higher ( p M ) concentration. However, they appear to bind to a slightly different site of the GABAA receptor chloride channel complex in order to do so, as deduced from additivity of barbiturate and steroid effects on binding and chloride flux (e.g., Turner et al., 1989) and the fact that they also increase channel opening frequencies (Twyman and Mcdonald, 1992). Some steroid derivatives, including pregnenolone sulfate, dehydroepiandrosterone sulfate, cortisol, and the synthetic RU5 135, inhibit GABA, receptor function noncompetitively ( p M potency for first three; RU5135 is low nM), through actions at more than one class of site. Different combinations of clones subunits appear to differ in their response to steroids (e.g., Zaman et al., 1992b), correlating with reported regional differences in steroid potency (Lan et al., 1991). The picture has been complicated by the recent discovery of other potential sites of neurosteroid action, including glycine receptors (Wuet al., 1990; Prince and Simmonds, 1992), calcium channels (Ffrench-Mullen and Spence, 1991), and the N -
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methyl-D-aspartic acid (NMDA) subclass of excitatory amino acid receptors (Wu et al., 1991).
E. Other General Anesthetics
A number of general anesthetic agents are thought to act, at least in part, by enhancing GABAergic inhibitory neurotransmission (Tanelian et al., 1993). Besides barbiturates and steroids, discussed above, these include the injectable anesthetics etomidate and althesin (Saffan)and several inhalational anesthetics (Nakahiro ef al., 1989; Jones et al., 1992). Recently added to the list is propofol (2,6-diisopropylphenol),a new shortacting intravenous general anesthetic which resembles barbiturates and steroids in its ability to prolong burst duration, to open channels by itself at higher concentrations (bicuculline sensitive), and to produce these effects without block by the benzodiazepine antagonist flumazenil (Hales and Lambert, 1991). It was inactive intracellularly and produced a modest enhancement of glycine-induced currents. Most of these observations have been paralleled in binding and chloride flux measurements and in some in vivo observations of inhibition of neuronal firing (Peduto et al., 1991). Findings include lack of effect on flunitrazepam binding, enhancement of GABA binding and of TBPS binding in the presence of GABA (inhibits without GABA), and flumazenil-insensitive enhancement of chloride flux into membrane vesicles in the presence of GABA (no effect without). Data suggest that y-subunits are involved in some of these responses as well as responses to benzodiazepines (L.-H. Lin et al., 1993a; Uchida et af.,1993). Other potential targets for general anesthetics include excitatory amino acid receptors (L.-H. Lin et al., 1993b). E Alcohol
Alcohol is a very important drug in terms of its social use and abuse. There is a large and rather controversial literature on the effects on ethanol on GABAA receptors (reviewed, with other potential targets, in Deitrich et al., 1989; Harris and Allan, 1989;Gonzales and Hoffman, 1991). Besides GABA, receptors, prime contenders for sites of ethanol’s actions include NMDA receptors (e.g., Lima-Landman and Albuquerque, 1989)and SHT, receptors (e.g., Lovinger and White, 1991). The potentiating effect of ethanol on GABAA receptors seems to depend on many factors, including brain region (e.g., cerebellum is more sensitive than hippocampus; Proctor e f al., 1992), adrenergic modulation (A. M.-Y. Lin et al., 1993), genetic
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background (e.g., selection for long sleep, LS, vs short sleep, SS, mice; Allan and Harris, 1986; Wafford et al., 19901, subunit composition (e.g., need for y2,-subunit, Wafford et al., 1991; but see Sigel et al., 19931, and post-translational modification (Wafford and Whiting, 1992). Subunit composition differences would appear to explain regional and genetic differences, but nature may not be so cooperative. Thus the hippocampus contains y2,-subunits, and there is no difference in y2,-subunit mRNA levels in different brain regions between LS and SS mice (Zahniser et al., 1992, by quantitative PCR; we have verified this in whole brains by RNase protection, J. B. Wang and D. R. Burt, unpublished results). A possible explanation is in terms of differential GABAA receptor post-translational processing between LS and SS mice, particularly phosphorylation of the serine residue in the alternatively spliced y,,-subunit. In a different model of alcohol sensitivity, the alcohol tolerant (AT) and alcohol nontolerant (ANT) rats, the major explanation of another behavioral difference, sensitivity to diazepam-induced ataxia in ANT rats, appears to be in terms of an Arg to Gln change in the a,-subunit extracellular domain at residue 100 (Korpi et al., 1993). This Gln residue is equivalent to 101 in the a,-subunit, where a His residue similarly provides diazepam sensitivity (Wieland et al., 1992). The change correlates with the increased efficacy of benzodiazepine agonists in competing for cerebellar binding of [3H]Ro 15-4513 binding in ANT rats (Uusi-Oukari and Korpi, 1991). In both models, there could also be contributions involving other subunits not yet examined, e.g., a4,or other potential targets for ethanol such as nicotinic, NMDA, kainate, or SHT, receptors.
G. Calcium, Zinc, Lysine There are a few miscellaneous substances in the body which affect GABAA receptors and may be of physiological relevance. The most obviously relevant is calcium, an important intracellular mediator of signal transduction which affects phosphorylation status. Firing-evoked calcium entry reduces GABA, currents in hippocampal pyramidal cells (Pitler and Alger, 1992), perhaps by inducing dephosphorylation (Chen et al., 1990; but see Shirasaki ef al., 1992, for a possible direct effect of ATP). Zinc is an ion with a less-defined role which also inhibits GABA, receptor function in some cells, mainly by reducing the frequency of channel opening (Legendre and Westbrook, 1991; Smart, 1992). As already noted, the y2-subunit seems to confer zinc insensitivity. The amino acid lysine has GABA-enhancing or -mimicking effects in uiuo and in uitro (Chang et af., 1991).
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H. Regulation by Chronic Drugs On chronic administration, several of the drugs which affect GABAA receptors acutely seem to produce regulatory changes in the properties of the receptors distinct from the agonist-induced immediate desensitization and slower downregulation already described. Rather, there appears to be a functional “uncoupling” of the drug from the receptor. The most likely explanations for these effects, which are not unlike those observed for other receptors (Hadcock and Malbon, 1991),are in terms of regulatory changes in receptor subunit composition, phosphorylation. etc., and such changes are now becoming established. The two classes of drugs which have drawn the most attention, both of obvious clinical relevance, are chronic benzodiazepines and chronic alcohol. I n vivo and in vitro, both benzodiazepines (e.g., Roca et al., 1990b) and alcohol (e.g., Mhatre and Ticku, 1989; Morrow et al., 1990) produce changes in GABAA receptorrelated binding and function which accompany tolerance and dependence, and these changes have been shown to be accompanied further by changes (up and down) in subunit mRNA levels (for benzodiazepines, Heninger et al., 1990; Kang and Miller, 1991; O’Donovan er al., 1992; for alcohol, Buck et al., 1991; Montpied et al., 1991b). Benzodiazepine inverse agonists seem to produce changes opposite those of agonists (Primus and Gallager, 1992), and, in rats chronically treated with alcohol, results include a cerebellar decrease in a , message accompanied by an increase in a6message (Mhatre and Ticku, 1992a; Morrow et al., 1992). These subunit mRNA changes, which suggest regulatory subunit switching, are being followed up at the protein level (Mhatre et al., 1993). There is no simple correlation among the behavioral, biochemical, and molecular biological measurements in terms of timing, so that it is likely that several mechanisms are occurring at once for both alcohol and benzodiazepines. These and drugs with similar actions listed above (e.g., steroids, barbiturates, other anesthetics) produce various degrees of cross-tolerance and dependence (e.g., Buck and Harris, 1990; Crabbe er d., 1991; Allan et a)., 19921, suggesting some mechanisms in common. V. DISTRIBUTION OF GABA RECEPTORS
A. Central Nervous System
GABA, receptors are essentially ubiquitous in the brain and spinal cord. A major enterprise at present is to map the distribution of individual subunits, through their mRNAs (in situ hybridization; e.g., Laurie et
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al., 1992a; Persohn et al., 1992; Wisden et al., 1992) or subunit-specific antibodies (immunohistochemistry, e.g., Benke et al., 1991a,b; Zimprich et al., 1991; Fritschy et al., 1992). The goal is not only to help establish the subunit composition of native receptors in different neurons or brain regions, by seeing which subunits go together, as discussed above, but also to see which combinations of subunits occur in neurons or regions of known function as a possible guide to developing more selective drugs for those combinations and functions. Notable findings in this arena include the almost exclusive localization (in adults; Poulter et al., 1992) of a,-subunits to synapses of cerebellar granule cells (Kato, 1990; Liiddens et ul., 1990; Baude et ul., 1992; a I and a5also occur there, Bovolin et al., 1992a,b)and predominant localization of p,-subunits to the retina (Cutting et al., 1991). In each case, as already noted, pharmacological peculiarities of GABAA receptors in the host neurons accompany the subunit’s presence. Similarly, there is a frequent association of 6 with a4-or a,-subunit mRNAs in neurons (thalamic nuclei or cerebellar granule cells, respectively) not responding to benzodiazepine agonists. Many past studies of GABA, receptor heterogeneity have contrasted hippocampus and cerebellum, and newer studies of subunit distribution find clear differences between these regions, including a preponderance of a5and p, in the hippocampus and of aj and pz13in the cerebellum. Space considerations preclude a more detailed description of the distribution of the subunits. The interested reader is referred to Laurie et al., (1992a), Persohn et al. (1992), and Wisden et al. (1992) for the most complete studies of subunit mRNAs to date and to Fritschy et al. (1992) for the most complete study of antibody staining.
B. Peripheral Nervous System
Many cells of the peripheral nervous system also respond to GABA through GABAA receptors (Erdo and Wolff, 1990; Ong and Kerr, 1990). Prominent loci include dorsal root ganglia, where receptor presence probably reflects GABAergic synapses on primary afferent terminals in the dorsal horn of the spinal cord, and the enteric nervous system, where GABA neurons affect gut motility (mostly GABA,). Other sites where GABA appears to play a role in peripheral innervation include the gallbladder, urinary bladder, and lung. In sympathetic ganglia (e.g., Newland and Cull-Candy, 1992), GABA is taken up from and released from glia, but is also present in preganglionic neural elements.
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C. Glial Cells
An important locus of nonneuronal GABAA receptors is glial cells of the CNS and periphery (reviewed in von Blankenfeld and Kettenmann, 1992). Most glial cells, e.g., cultured astrocytes and oligodendrocytes, have a relatively high, pump-maintained, internal chloride concentration of about 40 mM, so that net GABAA receptor currents are inward (depolarizing, corresponding to chloride efflux). The properties of these responses are generally similar to those of the typical hyperpolarizing responses in neurons (e.g., blocked by bicuculline and picrotoxin and potentiated by benzodiazepines, barbiturates, and steroids), but there are exceptions. Astrocytic GABAA receptors differ from most in that DMCM slightly enhances GABA-induced currents (Bormann and Kettenmann, 19881, a pharmacology mimicked by various y l-subunit-containing combinations (von Blankenfeld et af., 1990; Puia et af., 1991) and associated with the presence of yl-subunits in astrocytes (Bovolin et af., 1992b), along with a l , a2,p , , and p3 (and some yZsand y3).Oligodendrocytic GABAA receptors differ from most by showing lack of positive cooperativity for GABA (von Blankenfeld et af.,1991), also found for many double-subunit combinations (Sigel et af., 1990). The functional role of glial GABAA receptors remains unknown, but suggestions have included buffering extracellular chloride, similar to the presumed glial role in buffering extracellular potassium (Ritchie, 1992). D. GABA Receptors Outside the Nervous System
GABA, receptors are found on many types of cells outside the central and peripheral nervous systems (Erdo and Wolff, 1990; Ong and Kerr, 1990). Especially prominent are selected components of the endocrine system, including glucagon- and somatostatin-secreting cells of pancreatic islets (Michalik and Erecinska, 1992), catecholamine-secreting chromaffin cells of the adrenal medulla, anterior pituitary cells of several types (Valerio et al., 1992), especially lactotrophs, and melanotrophs of the pituitary intermediate lobe (e.g., Louiset et af., 1992). Pancreatic GABA probably comes from GAD in insulin-secreting /3 cells. This GAD appears to be the initial target of autoantibodies in insulin-dependent (juvenile or type I) diabetes (Baekkeskov et af., 1990). In most of these sites, GABAA receptors serve to reduce hormone secretion. The adrenal medulla contains GABAA receptor al- and &,-subunits but not a2-or a,-subunits, as determined from cDNA library screening and Northern blots (Ymer et
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al., 1989b). A PCR-based study of subunits present in the rat anterior pituitary gland (Valerio er al., 1992) found evidence for messages for a,-. PI-,p3-,and y2s-subunits,but not a5-,p2-,yZL-,and $-subunits. The direct biochemical evidence fo GABAA receptors in pancreatic islets is thus far just from antibodies against brain @-subunits(Rorsman et al., 1989), with good functional data as well. Another site for GABA and GABAA receptors, apparently without neuronal involvement, is the female reproductive system, particulary ovary, fallopian tube, and uterus. Regulation by reproductive steroids of GABAA receptors in this site (Majewska and Vaupel, 1991) makes sense, but such regulation even seems to occur in the brain (Finn and Gee, 1993). Other sites with some evidence for GABA, receptors include pancreatic exocrine cells, renal tubular epithelium, hepatocytes, gastric mucosa, cerebral arteries, oocytes, sperm, platelets, thymus, and spleen. E. Developmental Changes
There is some evidence that GABA functions as a trophic factor during development (e.g., Madtes and Redburn, 1983;Wolff eral., 1993). Indeed, many embryonic neurons appear to go through a stage of transient expression of GABA immunoreactivity (Schaffner ef al., 1993). Although there is no clear division into embryonic and adult subunits, the early appearance of some GABAA receptor subunits in embryos may be related to this function. Moreover, GABA is frequently depolarizing early in nervous system development, with little desensitization, and this provides a major source of excitation to developing neurons which may be important in appropriate circuit formation (Cherubini et al., 1991). A developmental increase in benzodiazepine sensitivity of the hippocampus has been reported (Rovira and Ben-Ari, 1991), presumably reflecting changes in y 2 or other subunits (e.g., Killisch et al., 1991). A similar developmental decrease in sensitivity to zinc inhibition of GABA responses in cultured superior cervical ganglion neurons (Smart, 1992) may again involve the y2subunit. Possible developmental exchanges among functionally dissimilar subunits would resemble apparent switching among subunits during drug tolerance and dependence, as discussed above, and may reflect changes in innervation patterns and receptor roles, while exchanges among functionally similar subunits could change receptor regulatory properties. Among a-subunit proteins in several regions of rat brain, a I - and a5subunits are very low at birth and increase dramatically with age up to about 3 months, whereas a2and a3are present in high levels at birth and
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continue to be high, with a tendency to decline in older rats (McKernan et a/., I991a). These results generally agree with changes in a-subunit mRNA levels in rats (e.g., Garrett et a/., 1990; Gambarana et al., 1991) and mice (Wang et a/., 1992a), except that a5mRNAs tend to start high at birth and drop with development (MacLennan et al., 1991; Bovolin et al., 1992a; Laurie et a/., 1992b; Poulter et a/., 1992). For rat @-subunit mRNAs, PI is high at birth and declines to adult levels by 5-7 days of age (Garrett et al., 1990), while p2 and p3 increase following birth to a maximum at about 3 weeks (Gambarana et a/., 1991). The & mRNA appears relatively early in embryonic develoment (Laurie et al., 1992b; Poulter et a/., 1993). In mouse cerebellum, PI mRNA appears later than p2 or p3 (Zdilar et al., 1992). Total y z mRNAs show a modest general increase with age (e.g., Gambarana et a/., 1991, in rats). In both mice (Wang and Burt, 1991) and rats (Bovolin et a/., 1992a), the short form ( y Z s )is high at birth and changes little with development, while the long form (yZL)shows a dramatic developmental increase. In rats, yI and y3 mRNAs drop with development (Laurie et al., 1992b). In mice, the y I mRNA shows little change with postnatal development (Wang et al., 1994). The 6 mRNA shows a developmental increase similar to that of aI in mice (Wang et al., 1992b)and rats (Laurie et al., 1992b). In the prenatal rat spinal cord, a detailed study of 13 receptor subunit mRNAs by in situ hybridization and qualitative PCR (Ma et a/., 1993) has revealed three major patterns of expression: (1) The a4@,y,combination is expressed early (embryonic day 13, about as soon as GABA appears) and transiently, and appears to be associated with proliferating zones and neurogenesis. (2) The a5p2y3combination is also transiently expressed, only in the mantle zone. (3) The a2,a3,&, and y 2 subunits are widely coexpressed in gray matter, with dramatic early increases and a persistence into adulthood. These four subunits are most clearly associated with spinal synapses. Developmental changes of GABA, receptors in the brain continue into old age, with major decreases in a Imessage in cortex but not cerebellum, where a6 message actually increases (Mhatre and Ticku, 1992b). E Invertebrate GABA Receptors
GABA is a major inhibitory neurotransmitter in invertebrates as well as in vertebrates, but differs in playing a role in neuromuscular transmission as well as in neuron-neuron communication. Most described invertebrate GABA receptors resemble vertebrate GABA, receptors in being chloride channels, some of which are modulated by benzodiazepines and
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barbiturates, but there are important pharmacological differences as well (Sattelle et al., 1991). Although many GABA responses are blocked by picrotoxin, most are insensitive to bicuculline. Some responses are excitatory and are carried by sodium. Invertebrate GABA receptors appear to be important targets for certain insecticides, including lindane and cyclodienes such as dieldrin, chlordane, and endrin (Eldefrawi and Eldefrawi, 1987). The ability of insects to develop resistance to cyclodienes has been used indirectly to clone a putative GABAA receptor subunit from the fruit fly Drosophila melanogaster (ffrench-Constant et al., 1991). Resistant strains were crossed to sensitive ones to map the single locus (Rdl)conferring resistance, and chromosome walking in conjunction with X-rayinduced chromosome rearrangement was used to identify a cosmid clone which conferred sensitivity to resistant flies receiving it through P-elementmediated germ-line transformation. This genomic clone was used to screen a cDNA library, yielding the final cDNA. When translated, this gave a GABAA receptor subunit-like protein (27-29% identity to mammalian subunits), whose differences from mammalian GABAA receptor subunits include 80 extra amino acids, mostly glycines, in the M3-M4 intracellular loop. In the absence of an intron in the middle of M2, the structure of the gene (>25 kbp) resembles mammalian genes for glycine receptors more than those for GABAA receptors (ffrench-Constant and Rocheleau, 19921, and there is also a slightly higher (31-32%) amino acid identity to mammalian glycine receptor subunits. The gene shows extensive alternative splicing (ffrench-Constant and Rocheleau, 1993). The mutation which prevents channel block by dieldrin or picrotoxinin is an Ala to Ser or Gly transition in M2 (ffrench-Constant et al., 1993a,b). Another invertebrate GABAA receptor subunit has been cloned by homology screening of a genomic library from the pond snail Lymnaea stagnalis with a bovine &-subunit clone (Harvey et al., 1991). The corresponding cDNA was isolated by a PCR variant (rapid amplification of cDNA ends, RACE), after unsuccessful attempts to screen cDNA libraries. Not suprisingly, the resulting subunit is very p like (ca. 50% amino acid identity). Indeed, in combination with bovine a,-subunits, it can replace p-subunits to form heteromeric functional channels in Xenopus oocytes. By itself it forms homomenc channels with a finite probability of spontaneous opening in the absence of GABA, sensitive to blockade by bicuculline and cyclodienes, and directly activated by peripheral benzodiazepine receptor ligands (Aaman et al., 1992a). These results emphasize the very strong conservation of GABAA receptor subunits through evolution.
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VI. GABA RECEPTORS AND DISEASE A. Epilepsy
Many considerations argue for an involvement of GABA in at least some forms of inherited and acquired epilepsy (Meldrum, 1989;Tasker and Dudek, 1991). Clinically, some of the most effective drugs in controlling seizures, benzodiazepines and barbiturates, augment GABA-mediated inhibition through actions at GABAA receptors. Experimentally, seizures can be induced by a variety of drugs which interfere with GABA’s actions, whether at the level of its biosynthesis, release, or receptors. These effects are mediated at discrete sites (Gale, 1989). More generalized changes in parameters related to GABA, including GABAA receptors, have been reported in several animal models of inherited epilepsy. For instance, binding and chloride flux changes accompany susceptibility to audiogenic seizures in DBA/2 mice (e.g., Yu et al., 1986; Schwartz et al., 1989), and there is a greater reduction in a,-subunit mRNA following chronic ethanol in withdrawal seizure prone (wsp) mice (genetically selected for susceptibility to handling-induced seizures following ethanol withdrawal) than in withdrawal seizure resistant (wsr) mice (Buck et al., 1991). A similar connection has been made for GABABreceptors and absence seizures in lethargic mice (Hosford et al., 1992). Many genes contributing to epilepsy are being mapped in mice (e.g., Rise et af., 1991)and humans (e.g., Durner et al., 1991), and some such genes are likely to be related to GABAA receptors.
B. Alcoholism As noted above, GABAA receptors appear to be an important site for the acute effects of alcohol, and there are regulatory changes in receptor function and subunit message levels that accompany alcohol tolerance and dependence, suggesting a role for GABA, receptors in these phenomena. There are changes in other potential alcohol targets, e.g., NMDA receptors and voltage-dependent calcium channels (Buck and Harris, 1991), as well. Although obviously related, tolerance and dependence are distinct from alcoholism, or the abuse of alcohol, and there is less evidence linking GABAA receptors to alcoholism (Samson and Harris, 1992). The reward aspects of alcohol consumption and abuse are more likely to involve another neurotransmitter system, such as dopamine (Koob, 1992).
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C. Hepatic Encephalopathy
Liver disease, particularly with shunting of intestinal blood so as to bypass the liver, is frequently associated with a severe depression of brain function termed hepatic encephalopathy. Although the disease is commonly related to disturbances of nitrogen metabolism (excess ammonia production), there is considerable evidence for excess stimulation of GABAA receptors, perhaps by elevated levels of endogenous benzodiazepine agonists (Basile et ul., 1991). The evidence includes amelioration of symptoms in humans by flumanzenil, a benzodiazepine receptor antagonist. Available data do not exclude a more direct contribution from changes in GABAA receptors themselves. D. Other Diseases
Drugs acting at GABA, receptors influence a variety of behaviors, presumably reflecting the wide distribution of these receptors in the brain. Both factors suggest that disorders of GABAA receptors could contribute to a varitety of brain disorders, including anxiety, depression, schizophrenia, and disorders of movement, eating, sleeping, agression, memory, etc. Genetic mapping may be expected to connect many other diseases to GABAA receptor subunits.
VII. COMPARISON WITH CLYCINE RECEPTORS As already noted, glycine is another inhibitory neurotransmitter in the central nervous system, particularly important in the spinal cord and brain stem. It is also an important modulator of NMDA receptors. Glycine receptors are perhaps best known as the major site of action of the antagonist strychnine, a convulsant. Like GABAA receptors, they are chloride channels, with a similar set of four conductance states (Hamill et al., 1983). (Also like GABAA receptors, they are potently blocked by the synthetic steroid RU5135.) Several subunits have now been cloned by the group of Betz in Germany (Betz, 1990, 1991) and shown to resemble closely GABAA receptors in their primary amino acid sequences. These include at least four a-subunits, which bind glycine and strychnine (weakly for an a2 variant, a2[E167G], sometimes present in neonatal rat spinal cord; cq and a4are only minor constituents at all ages), and at least one j3-subunit, whose mRNA appears to be much more widely distributed in brain than mRNAs for known a-subunits. Other similarites of glycine
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receptors to GABAA receptors include desensitization by agonist and alternative splicing of a , and a2 mRNAs. In the case of the a , (adult)subunit, the latter adds eight amino acids including a possible phosphorylation site (by alternative splice acceptor site selection) in almost the same place as eight amino acids are added to the GABAA receptor yz-subunit (and four to GABAA p4),just after M3. The glycine receptor q s u b u n i t (neonatal) alternative splicing involves alternate exon usage in the extracellular domain, to produce little apparent difference in the final proteins. As is the case for GABAA receptors, phosphorylation by protein kinase A has been reported to modulate glycine receptor function (Song and Huang, 1990), in this case increasing the probability of channel opening. Reduced expression of the adult isoform of the glycine receptor, detected by monoclonal antibody 2b against an epitope on the N-terminus of the a , subunit, has been linked to the mouse mutant spastic (Becker et a/., 1992), which exhibits symptoms resembling strychnine poisoning. N o accompanying change in a,-subunit message levels was detected by Northern blots. Some interactions between GABA, and glycine receptors probably occur at the cellular level. Many neurons contain both types of receptor (some even contain both transmitters, Todd and Sullivan, 1990). and crossed desensitization between the two receptors has been reported (Barker and McBurney, 1979; Hamill et a/., 1983). VIII. FUTURE PROSPECTS After all of the GABAA receptor subunit genes are mapped and characterized, the use of embryonic stem cells and homologous recombination to facilitate receptor subunit gene deletion or modification one at a time in transgenic mice (Zimmer, 1992) should facilitate understanding of the roles of the many GABAA receptor subunits in uiuo and perhaps provide mouse models of human disease. Similarly, in cultured neurons, use of Herpes simplex-based vectors (Geller et al., 1991) to add or subtract subunits, or just antisense oligonucleotides in the medium for subtraction (Listerud et al., 1991), could provide a useful correlate in uitro. Further progress may be expected in the development of cell lines which express defined combinations of subunits, either through immortalization of a given cell type (Cepko, 1989), as for GTl cells (Hales et al., 1992), o r permanent transfection of subunits into an existing cell line (Moss et a/., 1990). These should prove invaluable in the empirical development of more selective drugs. Similarly, increased understanding of endogenous compounds acting on GABA, receptors, including various peptides, endozapines, and steroids, could lead to new classes of drugs. Drug design
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will be aided by site-directed mutagenesis to improve knowledge of key residues in drug interactions. The major immediate problem remains just to sort out the subunit arrangements of native GABA, receptors, ideally starting with cell lines or tissues expressing a single subtype. From these data we should be able to learn the rules for assembling subunits. Then will come the goal of determining how the rules are set through transcriptional controls and subunit-subunit interactions during assembly. There will be a lot more site-directed mutagenesis in all of this. A long-term goal, of course, is complete three-dimensional structure determination. Acknowledgments 1 thank Drs. Jay Yang and Ganesan Kamatchi for helpful comments. This work was supported in part by USPHS Grant AA07559 and by a Special Research Initiative award from the UMAB Designated Research Initiative Fund.
References Alger. B. E.. and Nicoll. R. A. (1982). Pharmacological evidence for two kinds of GABA receptor on rat hippocampal pyramidal cells studied in vitro. J . Phvsiol. (London)328, 125-14 I . Allan. A. M.. and Harris, R. A. (1986). Gamma-aminobutyric acid and alcohol actions: Neurochemical studies of long sleep and short sleep mice. LiJre Sci. 39,2005-2015. Allan. A. M., Zhang, X., and Baier, L. D. (1992). Barbiturate tolerance: Effects on GABAoperated chloride channel function. Bruin Res. 588, 255-260. Allen. C. N . , and Albuquerque, E. X. (1987). Conductance properties of GABA-activated chloride currents recorded from cultured hippocampal neurons. Brain Res. 410,159-163. Amin, J., and Weiss, D. S. (1993). GABA, receptor needs two homologous domains of the 0-subunit for activation by GABA but not by pentobarbital. Nature (London) 366, 565-569. Anderson. S. M. P., De Souza, R. J., and Cross, A. J. (1993). The human neuroblastoma cell line, IMR-323. possesses a GABAA receptor lacking the benzodiazepine modulatory site. Neuropharmacology 32,455-460. Angelotti, T . P., and Macdonald, R. L. (1993). Assembly of GABAAreceptor subunits: a d ,and aI/3,yZssubunits produce unique ion channels with dissimilar single-channel properties. J . Neurosci. 13, 1429-1440. Angelotti, T. P., Uhler, M. D., and Macdonald, R. L. (1993). Assembly of GABAAreceptor subunits: Analysis of transient single-cell expression using a fluorescent substratel marker gene technique. J . Neurosci. 13, 1418-1428. Avoli. M. (1992). Synaptic activation of GABAA receptors causes a depolarizing potential under physiological conditions in rat hippocampal cells. Eur. J . Neurosci. 4, 16-26. Baekkeskov, S., Aanstoot, H.-J., Christgau, S . , Reetz, A.. Solimena, M.,Cascalho, M., Folk F., Richter-Olesen, H., DeCamilli. P.,and DeCamilli, P. (1990). Identification of the 64K autoantigen in insulin-dependent diabetes as the GABA-synthesizing enzyme glutamic acid decarboxylase. Narure (London) 347, 151- 156. Barker, J. L.. and McBurney, R. N. (1979). GABA and glycine may share the same conductance channel on cultured mammalian neurones. Nature (London)277, 234-236. Barnard, E. A., Burt, D. R., Darlison, M. G . , Fujita, N . , Levitan, E. S., Schofield, P. R . . Seeburg, P. H.. Squire, M. D., and Stephenson, F. A. (1989). Molecular biology of the
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CHAPTER 10
Chloride Channels along the Nephron Erik M. Schwiebert, Anibal G. Lopes,* and William B. Guggino Department of Physiology, Johns Hopkins University School of Medicine, Baltimore. Maryland 21205: and *Institute de Biofisica Carlos Chagas Filho, Universidade do Rio de Janeiro. Rio de Janeiro, RJ. Brazil
I . Introduction 11. Chloride Transport in Specialized Cells Associated with the Glomerulus A. Chloride Transport in Macula Densa Cells of the Juxtaglomerular Apparatus
B. Chloride Transport in Mesangial Cells of the Glomerulus 111. Chloride Transport in the Proximal Nephron: Proximal Convoluted Tubule through
IV.
V.
VI. VII. VIII.
Thick Ascending Limb A. Chloride Transport in the Proximal Tubule B. Chloride Transport in the Thin Descending (DLH) and Thin Ascending Limbs (ALH) of Henle's Loop C. Chloride Transport in the Thick Ascending Limb of Henle's Loop Chloride Transport in the Distal Nephron: Distal Convoluted Tubule through the Collecting Duct A. Chloride Transport in the Distal Convoluted Tubule (DCT) B. Chloride Transport in the Connecting Tubule (CNT) C. Chloride Transport in the Cortical Collecting Duct (CCD) D. Chloride Transport in the Outer Medullary Collecting Duct (OMCD) E. Chloride Transport in the Inner Medullary Collecting Duct (IMCD) Chloride Transport in Cultured Cell Models of Renal Ion Transport A. Xenoprrs Kidney Cell Line (A6) B. Madin-Darby Canine Kidney Cell Line (MDCK) Chloride Channels in Intracellular Compartments Renal Chloride Channel Biochemistry and Molecular Biology Summary References
1. INTRODUCTION
Chloride (C1-) transport along the nephron is involved in several key physiological processes such as tubuloglomerular feedback (TGF), macula Currenr Topics in Membranes, Votume 42 Copyright 0 1994 by Academic Press, Inc. All rights of
reproduction in any form reserved.
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densa-mediated renin release, urinary acidification, cell volume control, and acidification of intracellular compartments. C1- is also the most abundant inorganic anion in body fluids. Under normal conditions, the human kidney filters about 18 mol of C1- per day across the glomeruli, the majority of which is reabsorbed along the nephron by mechanisms specific to different proximal and distal nephron segments (Berry and Rector, 1991 ; Koeppen and Stanton, 1992). Figure 1 depicts the relative percentage of C1- reabsorption in different segments along the nephron. The majority
coriex Distal Convoluted Tubule @CT)
Connccling Tubules (CNT)
/ Micula Dens.
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,
C0rtiC.l Collecling Duct (CCD)
\ Thick / Ascending Limb PAL)
-----_ Outer Medulla
\
20-25%
_---_Outer
Medullary / Collrtlng Duct (OMCD)
. cI.
3%
\ \
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Ascending Tbh Limb (ALH)
/
W
W FIGURE 1 Illustration of the handling of CI- ions by segments along the nephron. This figure illustrates CI- reabsorption; however, putative pathways and physiological conditions where CI- secretion may occur in various nephron segments are discussed where appropriate and are depicted in cell models included in Figs. 2 and 3.
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of C1- (approximately 50-67% of the filtered load) is reabsorbed by the proximal tubule in parallel with sodium ( N a + ) (Berry and Rector, 1991; Weinstein, 1992; Koeppen and Stanton, 1992).In the thick ascending limb, Na+ and CI- are reabsorbed in concert; although, less salt (approximately 20-25% of the filtered load) is reabsorbed in this segment (Berry and Rector, 1991 ; Reeves and Andreoli, 1992a; Koeppen and Stanton, 1992). Only 5% of the filtered load of C1- is reabsorbed in the distal tubules, while approximately 3% is reabsorbed in the collecting duct (Berry and Rector, 1991; Koeppen and Stanton, 1992). It is the distal nephron that is responsible for “fine” regulation of NaCl balance (Berry and Rector, 1991; Koeppen and Stanton, 1992), while it is the proximal nephron that is responsible for “bulk” reabsorption of NaCl. Less than I% of the filtered load is excreted in the urine under physiological conditions (Berry and Rector, 1991; Koeppen and Stanton, 1992). The objective of this review is to provide a synopsis of the mechanisms of C1- transport in specialized renal cell types such as mesangial cells and macula densa (MD) cells, nephron segments such as proximal tubule (PT), thick ascending limb (TAL), cortical collecting duct (CCD), and, in a few examples, cell culture models of renal ion transport such as the Madin-Darby canine kidney (MDCK) and A6 cells. It is our intent to focus each part of this review on specific cell types or segments of the nephron. Our discussion of the cellular mechanisms of C1- transport in each segment or cell type consists of: ( I ) original studies which identified C1- transport in a cell type or nephron segment; (2) studies which identified the specific mechanisms by which C1- transport was achieved (CI- channel or C1- transporter); and ( 3 ) patch-clamp studies which characterized the properties of C1- channels in a nephron segment or renal cell type. When possible and where defined, the functional role of C1- channels as well as the regulation of channels are discussed. II. CHLORIDE TRANSPORT IN SPECIALIZED CELLS ASSOCIATED WITH THE GLOMERULUS A. Chloride Transport in Macula Densa Cells of the luxtaglomerular Apparatus
A group of specialized cells in the late TAL of Henle’s loop attach firmly to the extraglomerular mesangium at the angle formed by the afferent and efferent arterioles of the glomerulus (see also Fig. 1). This group of cells forms the MD, and the association of these cells with the glomerulus of the same nephron is called the juxtaglomerular apparatus ( JGA) (Schner-
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mann and Briggs, 1992). The JGA is a complex structure that contains a complete feedback regulatory system comprising sensory, integrative, and effector elements (Schnermann and Briggs, 1992). Changes in luminal fluid and electrolyte composition, specifically fluid delivery and NaCl concentration, at the MD lead to changes in both the filtration rate of the associated glomerulus and the rate of renin secretion from granular cells in the MD. Due to the development of an in uitro microperfusion system consisting of isolated, cortical TALs containing MD cells and an attached glomerulus, this preparation allowed for the direct study of the mechanism by which these cells sense C1- concentration in the tubular fluid (Skott and Briggs, 1987). Using this preparation, where effects from renal nerves or local hemodynamics were eliminated, Skott and Briggs (1987) measured renin secretion of the entire juxtaglomerular apparatus and observed a prompt stimulation of renin release rate by the MD cells in response to a decrease in tubular NaCl concentration in the cortical TAL. Therefore, studies were undertaken to examine the mechanisms of NaCl transport in MD cells, the regulation of renin release from renin-secreting cells, and the link between NaCl transport and renin secretion in this region of the nephron. Several original studies depleted or removed NaCl from the tubular fluid and stimulated renin release from the JGA (Abboud et al., 1979; Kirchner et al., 1978; Rostand et al., 1985). To determine the cellular mechanisms underlying C1- sensing in the JGA, MD cells were impaled with microelectrodes. Schlatter et al. (1989) demonstrated that the basolateral membrane potential (Vb,) was hyperpolarized by three maneuvers: ( 1 ) reduction of luminal NaCl concentration; (2) application of furosemide, an inhibitor of Na+,K+,2CI- cotransporter, to the luminal membrane; and (3) application of NPPB, a CIchannel blocker, to the basolateral membrane. Depolarization of V,, was achieved by reduction of basolateral C1- concentration. These experiments suggested that the electrical characteristics of MD cells were similar to those observed in the TAL. Additional data supporting this hypothesis were provided by Salomonsson et al. (1991), who measured intracellular C1- activity ([CI-IJ in MD cells with the Cl--sensitive dye SPQ. This group observed a sharp decrease of [Cl-Ij when furosemide was added to the tubule fluid, suggesting that the entry step across the apical membrane was via a Na+, Kf,2C1- co-transporter. On the other hand, NPPB added to the basolateral membrane increased [CI-Ii three-fold, providing evidence that the exit step across the basolateral membrane of MD cells was mediated by a C1- channel. In MD cells, Bell et al. (1989) and Lapointe et al. (1991) used intracellular microelectrode techniques to discover a C1- conductance in the basolateral membrane of these cells. The Cl-
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conductance was much larger (53 i 19%) than conductances for K + (23 8%) and Na+ (17 i 10%). Taken together, these results are compatible with a model for MD cells which is similar to that proposed for cells of the TAL (Greger, 1985). The model includes an electroneutral, furosemide-sensitive, Na+, K +,2C1- cotransporter in the luminal membrane and a C1- channel in the basolateral membrane (see Fig. 2). Until now, patch-clamp studies of the basolateral membrane of the macula densa or MD cells in culture have not been performed to characterize the type of C1- channel present. Development of a cell culture of renin-secreting JGA cells would facilitate these studies. Because the Na+,K+,2C1- co-transporter has a low K , for Na+,luminal CI - concentration has been proposed as the critical “sensory” criterion for the macula densa in tubuloglomerular feedback (TGF) (Schlatter et al., 1989; Persson et al., 1991). In order to demonstrate that this criterion existed, a series of studies by Lorenz ef al. (1990,1991) used techniques of in uirro microperfusion of cortical TAL that had an attached MD and glomerulus and found that renin secretion responded to luminal C1- concentration variations but was much less sensitive to changes of luminal Na+ concentration. Moreover, it was shown that luminal application of bumetanide, an inhibitor of N a f , K +,2C1- co-transport, stimulated renin secretion. These results suggest that the initial signal for the control of renin secretion was a decrease in the rate of luminal Na+,Kf,2C1- cotransport in MD cells and that C1- transport was the rate-limiting step in sensing whether to release renin or to decrease renin production. To define further the signaling mechanisms underlying the link between CI- transport and renin secretion in the juxtaglomerular, renin-secreting cells from isolated mouse glomerulus, Kurtz (Kurtz and Penner, 1989) measured both intracellular Ca2 using Ca2+-sensitivedye, Fura-2, and C1- currents. The results demonstrated that agonists which trigger an increase in intracellular Ca2+either via activation of phospholipase C and production of inositol 1,4,5-trisphosphate (IP,) (Kurtz and Penner, 1989) stimulate C1- currents. This result suggested that C1- channels in these cells are activated by Ca2+.The rise in intracellular Ca2+ concentration caused a marked CI- efflux which may inhibit renin release by some unknown mechanism. A similar mechanism involving a rise in intracellular Ca2+could underlie the known “osmometric” behavior of JGA cells, in which cell shrinkage is paralleled by inhibition of renin secretion (Frederiksen ef al., 1975; Skott, 1988). Finally, numerous studies have described a role for adenosine, a local metabolite and autacoid, in the tubuloglomerular feedback system (Arend et al., 1984; Churchill and Churchill, 1985; Churchill et al., 1979; Cook and Churchill, 1984; Itoh et al., 1985; Osswald et al., 1975; Tagawa and
*
+
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FIGURE 2 Cell models illustrating the mechanisms of CI- transport in cell types within the proximal nephron of the kidney. Out of convenience, cell models from the proximal nephron (glomerulus through thick ascending limb) are shown in this figure, and cell models from the distal nephron (distal convoluted tubule through collecting duct) are shown in Fig. 3. The JGA is used as the benchmark which separates proximal and distal nephrons.
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FIGURE 2 Continued For simplicity and clarity, only CI- transport mechanisms are shown. The asterisks in (A) represent multiple CI- trdnsporters/exchangers expressed in each membrane (see text for details).
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Vander, 1970; Weihprecht et al., 1990). N6-cyclohexyladenosine (CHA), an adenosine analogue and A, adenosine receptor agonist, inhibits the ability of low NaCl concentrations in the TAL to stimulate renin release. The selective A, adenosine receptor antagonist, 8-cyclopentyl- 1,3-dipropylxanthine (CPX) was shown to reverse the inhibitory effect of CHA (Weihprecht et al., 1990). Moreover, the inhibitory effect of high tubular fluid NaCl at the MD was blocked by CPX. Finally, CPX did not significantly affect renin secretion when luminal NaCl was low, suggesting that adenosine formation and/or release is dependent upon luminal NaCl concentration (Weihprecht et al., 1990). Further studies are necessary to elucidate the cellular mechanisms by which luminal NaCl concentration modulates renin release and adenosine production and by which angiotensin I1 causes renin release from granular cells of the MD. B. Chloride Transport in Mesangial Cells of the Glomerulus
To study the integration of the signal from MD cells to the glomerulus, Persson measured CI- activity in the juxtaglomerular interstitial spaces of Amphiuma during perfusion of the early distal tubule of the same nephron (Persson et al., 1988). It was observed that [CI-1 was higher in the interstitial space than in tubular fluid or plasma and increased when perfusion rate in the adjacent tubule was increased, reaching values higher than five-fold of isotonic values. This buildup of hypertonicity could be inhibited by bumetamide. Simultaneous measurements of single-nephron blood flow showed typical feedback inhibition parallel to the hypertonicity. Of interest, MD cells are in contact with extracellular mesangial cells, both of which form a microtissue not supplied with capillaries (Goormaghtigh, 1937,1939). Thus, this morphology is permissive for the generation of the hypertonicity. A close association of MD and extracellular mesangial cells to form a restricted space is important, because MD cells have a low Na+/K+-ATPaseactivity (Kashgarian et al., 1985; Schnermann and Marver, 1986) and are thought to have a low capacity for transport of NaCl. The ability of MDcells todefine the [Cl-1 in this space may represent the integrative step of this system. Both rnesangial cells and renin-secreting cells are in intimate contact with the JGA environment and respond to [CI-I. Mesangial cells reside in the intercapillary space of the glomerulus and have contractile fibers similar to those found in vascular smooth muscle cells. There is substantial experimental evidence supporting the idea that mesangial cells participate, through contraction, in the regulation of intraglomerular hemodynamics and, therefore, glomerular filtration rate (GFR)
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(Blantz et al., 1976;Schlondorff, 1987).The physiological role of mesangial cells in glomerular hemodynamics was examined directly by inducing mesangial cell lysis with an antithymocyte antibody serum (Blantz et al., 1993). These results suggest an important role for these cells in the regulation of the glomerular ultrafiltration coefficient, capillary hydrostatic pressure, and efferent arteriolar resistance (Blantz et al., 1993). It is well established that mesangial cell contraction, evoked by angiotensin I1 (AII) and vasopressin (AVP), depends on the production of IP,, a transient increase in Ca2t, and prostaglandin E, (PGE,) synthesis (Bonventre et al., 1986; Pfeilschifter, 1986; Pfeilschifter and Bauer, 1986; Hassid et al., 1986). Different experimental approaches have shown an increase in the C1- conductance across the plasma membrane of mesangial cells in response to A11 and AVP. The observation that a decrease in external chloride concentration [Cl-1, supressed the production of IP, and the resultant increase in the Ca2f induced by A11 and AVP led to the hypothesis that [Cl-1, may be the signal that, by modulating mesangial cell contraction, triggers tubuloglomerular feedback (Okuda et al., 1986,1989; Kremer et al., 1989). Using the patch-clamp technique, Ling et al. (1992b)found in rat glomerular mesangial cells (GMC) grown in the presence of insulin that 12% of cell-attached patches contained a 4-pS Cl--selective channel with a current-voltage ( I - V ) relationship that exhibited slight outward rectification. Mean NP, at resting potential was cO.1. Acute application of 100 nM A11 or 0.25 p M thapsigargin (to release Ca't) to the extracellular bath stimulated C1- channel activity (Ling et al., 1992b). In excised to 10-4Monthe cytoplasmic inside-out patches, the rise of Ca2+from side increased the open probability -100-fold (Ling et al., 1992b). When cells were grown in the absence of insulin, these channels were observed in only 4% of the cell-attached patches. Also, they were unresponsive to A11 and to thapsigargin and were less sensitive to activation by cytoplasmic Ca2+.Since a nonselective cation channel with a similar response to A11 and Ca2t was observed under the same conditions, the authors postulate that insulin-dependent C1- efflux and cation influx should promote depolarization of GMC cells and lead to voltage-dependent Ca2+channel activation, Ca2+influx, and GMC contraction (Ling et al., 1992b). These observations are in accordance with the observation that GMC contraction in response to vasoactive peptides also requires insulin (Ling et al., 1992b). Taken together, these results show that C1- channels as well as cation channels and calcium channels act in concert to depolarize the mesangial cell and allow for mesangial cell contraction. Studies are beginning to elucidate the complex regulation of these channels by insulin, angiotensin I1 (a mediator of tubuloglomerular feedback), and vasopressin. Since insu-
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lin binds to a receptor which displays intrinsic as well as associated tyrosine kinase activity and because increases in phosphoinositide turnover and intracellular calcium are important for the mesangial cell contractile response, substantial crosstalk between Ca’+-dependent protein kinases and tyrosine kinases may exist within the mesangial cell during the contractile response. In the coming years, the mesangial cell should serve as an excellent model for the study of signal transduction in the kidney. Moreover, the integration of mesangial cell and macula densa granular cell functions in the tubuloglomerular feedback response provides a unique opportunity for the study of linked intracellular and intercellular signaling pathways with C1- channels and CI-transporters serving as functional end points for these pathways. 111. CHLORIDE TRANSPORT IN THE PROXIMAL NEPHRON: PROXIMAL
CONVOLUTED TUBULE THROUGH THICK ASCENDING LIMB A. Chloride Transport in the Proximal Tubule
More than 50% of the filtered load of C1- is reabsorbed as NaCl in the proximal tubule, specifically in the late proximal convoluted tubule (PCT) (Chantrelle et al., 1985; Berry and Rector, 1991; Weinstein, 1992). Many studies have examined the relative importance of passive and active mechanisms underlying CI- reabsorption along the PT. Chantrelle examined the active and passive components of NaCl absorption in doubly perfused proximal convoluted tubules of rat kidney. Under conditions where the lumen was perfused with high C1- and the peritubular capillaries were perfused with an ultrafiltrate-like solution, approximately 50% of NaCI and water absorption was passive, driven by anion gradients, and 50% of the above was active. When the PCT lumen and peritubular capillaries were perfused with similar high C1- solutions, anion gradients were absent and all NaCl absorption was active (Chantrelle et al., 1985). With the knowledge obtained in these initial studies; laboratories have focused on the characterization of transcellular mechanisms of C1- transport across the proximal tubule. Numerous reviews have described electroneutral transporters or parallel exchange mechanisms in both the apical and the basolateral membranes of proximal tubule cells (Berry and Rector, 1991; Weinstein, 1992). Due to the limited length of this review and the overwhelming evidence for several mechanisms of CI- transport to the proximal tubule, the evidence for Cl- transport and exchange mechanisms is summarized. In the apical membrane, evidence exists for electroneutral NaCl transport in amphibian
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proximal tubule (Spring and Kimura, 1978; Guggino et al., 1982), whereas studies have also provided evidence for parallel Na+/H+ and CI-/OHexchange mechanisms (Warnock and Yee, 1981; Burnham et al., 1982; Shiuan and Weinstein, 1984; Chen et al., 1988; Karniski and Aronson, 1985,1987). In the basolateral membrane, studies suggest that several transporters mediate CI- transport including KCI co-transport (Sasaki et al., 1988; Ishibashi et al., 1990; Eveloff and Warnock, 1987), Na+-dependent Cl-/HCO; exchange (Ishibashi et al., 1990,1993; Alpern and Chambers, 1987; Grassl et al., 1987; Sasaki and Yoshiyama, 1988; Kondo and Fromter, 1990; Guggino et al., 1983), and Na'kdependent CI-/HCO; exchange (Ishibashi et al., 1990; Alpern and Chambers, 1987; Grassl et al., 1987; Chen et al., 1988; Sasaki and Yoshiyama, 1988; Kondo and Fromter, 1990; Kurtz, 1989; Grassl and Aronson, 1986). Several studies have focused on the contribution of C1- conductive pathways to C1- transport in the proximal tubule. Studies using either conventional or ion-sensitive microelectrodes showed a minor or negligible C1- conductance in the luminal and basolateral membranes of PCT and PST in rabbit and rat, suggesting that C1- channels played a small role in proximal tubule C1- transport (Berry and Rector, 1991 ;Burckhardt et al., 1984; Cardinal et al., 1984; Cassola et al., 1983; Ishibashi et al., 1990; Kuwahara et al., 1988; Sasaki et al., 1988; Shindo and Spring, 1981; Chen et al., 1988). However, several studies summarized below have found CI- conductances and the channels which underlie these conductances in the basolateral membrane as well as the luminal membrane of proximal tubule cells. Welling and O'Neil (1990a) used simultaneous measurements of tubule volume via videooptical imaging techniques and intracellular microelectrodes recording to monitor the effect of rapid changes in peritubular concentration of Cl- on the basolateral membrane voltage, V,,, in nonperfused rabbit proximal straight tubules (S2). Under isosmotic conditions, these authors observed an instantaneous and sustained depolarization of V,, of + 5 . 3 mV upon reduction of peritubular C1- from 120 to 4 mM which was not affected by bumetamide. This result was consistent with other studies above that demonstrated a small CIconductance with an apparent transference number for chloride (TCl)calculated to be 0.06. However, previous studies by Welling had illustrated the importance of C1- and K + to regulatory volume decrease in rabbit proximal straight tubule. Depletion of C1- from the tubules or inhibition of K + channels with barium attenuated regulatory volume decrease (RVD) induced by hypotonic cell swelling (Welling and Linshaw, 1988). Using similar methods of tubule volume measurement and intracellular microelectrode recording, hyposmotic challenge increased CI- and K + conductances in the
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basolateral membrane by approximately 100% during the peak of cell swelling (Welling and O'Neil, 1990b). These results are compatible with the presence of a swelling-activated CI- channel in the basolateral membrane of proximal tubule cells similar to those found in other tissues. Schild et al. (1991) and Macri et al. (1990,1993)also showed evidence for a swelling-sensitive C1- conductance in the basolateral membrane of rabbit proximal convoluted tubule. These studies provide an example of the minor contribution or the complete lack of conductances (active channels) measured under basal or steady-state conditions in the membranes of tubules or cultured cells. From such observations, the logical conclusion is that CI- conductive pathways are unimportant in transcellular ion and fluid transport. However, certain stimuli such as cell swelling or agonist activation may induce the activation of channels that were closed due to tonic inhibition or cause the insertion of channels held in vesicle pools beneath the cell membrane. Examples of C1- conductances which may be induced in the apical and basolateral cell membranes of the proximal tubule are discussed in the following sections. With the observation that a basolateral C1- conductance could be induced in the proximal tubule, the patch-clamp technique was utilized to characterize the channels that underlie this condutance. Using whole-cell patch-clamp recordings in isolated cells of Ambystornu proximal tubule, a macroscopic CI - conductance was identified that was enhanced reversibly by forskolin, an agonist for adenylyl cyclase, or by a membranepermeant analogue of cyclic AMP, dibutyryl-CAMP (dB-CAMP).The current could be inhibited by diphenylamine carboxylate (DPC), a C1-channel blocker. In single-channel recordings performed in symmetrical CI- solutions, a 10-pS channel was found with a linear I-V relationship in patches excised from the basolateral membrane (Segal and Boulpaep, 1990,1992). In cell-attached patches, dB-CAMP and forskolin activated as many as 10 channels in a single patch. In excised, inside-out patches, the channel was stimulated by ATP applied to the cytoplasmic face of the patch; ATPelicited channel activity was enhanced by addition of the catalytic subunit of protein kinase A. The open probability of the channel was also increased with depolarization and the anion selectivity sequence was determined to be I - > Br- > C1- >> F- > aspartate- and Cl- >> Na+ (Segal and Boulpaep, 1992). It is interesting that this channel shares some properties with the CFTR (cystic fibrosis transmembrane conductance regulator) CI- channel (Riordan et al., 1989) characterized in great detail in other, nonrenal epithelial cells (Cliff er al., 1992; Egan er ul., 1992; Gray ef al., 1989; Tabcharani et al., 1990) (see also Chapters 7 and 8 by Frizzell and Morris and Welsh and co-workers, this volume). However, this CI-
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channel in proximal tubule is activated by depolarization and has a different permselectivity sequence than CFTR. Nevertheless, it may represent an amphibian version of CFTR, a new isoform or splice variant of CFTR. or a channel closely related to CFTR. Gogelein and Greger (1986) described a voltage-sensitive channel in cellattached and excised patches of the lateral membrane of rabbit proximal tubules perfused in uitro. This channel has a conductance of 30 pS, does not discriminate between Na+ and K , and is twice as permeable to cations than to C1-. In cell-attached patches, the channel is nearly inactive at 0 mV, but is activated by depolarization. Despite a greater permeability to cations, experiments with CI- channel inhibitors showed that DPC blocks channel activity reversibly, whereas SITS inhibits channel activity in a partially reversible manner. Amiloride, an inhibitor of Na+ channels, has no effect on this channel. Of interest, Hunter (1990) described a swelling- and stretch-activated 25-pS channel that was permeable to cations as well as anions in the basolateral membrane of single proximal tubule cells isolated from Runa temporariu. This channel is also sensitive to voltage with open probability increasing with depolarization. Taken together, these data are compatible with the presence of a C1- channel in the basolateral membrane of proximal tubule cells. Additional studies are necessary in mammalian proximal tubules to characterize the types of C1- channels present and their sensitivity to various stimuli. A few studies have suggested that a C1- conductive pathway can also be induced in the apical membrane of proximal tubule cells. In a preparation of brush-border membrane vesicles, the appearance of a CI- conductance was demonstrated after stimulation by CAMP (Lipkowitz and Abramson, 1987). Patch-clamp recordings have also demonstrated the presence of C1- channels in the apical membrane of proximal tubule cells. Suzuki et ul. (1991) found a CI- channel in the apical membranes of rabbit proximal tubule cells in primary culture that was activated by parathyroid hormone (PTH) in cell-attached patches and by prolonged depolarization in inside-out patches. This channel expresses the following characteristics: a moderately outwardly rectifying Z-V relationship, a conductance of 23 pS at negative potentials and 33 pS at positive potentials, and a permeability ratio of chloride versus sodium of 10: 1 ( P c , - : PNa+= 10:I ). Since the channel is stimulated in a dose-response manner by PTH, by the catalytic subunit of protein kinase A (CSU-PKA), by purified protein kinase C (PKC), and by phorbol ester, a known PKC activator, the authors conclude that PTH activates the channel by signaling pathways which involve PKA and PKC (Suzuki et ul., 1991). Suzuki and co-workers defined the role of this channel in RVD with the aid of patch clamp and [CI-]; with SPQ fluorescence. RVD occurred +
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1 min after osmotic shock; [C1-Ii decreased simultaneously (Ogawa et al., 1992). Phorbol ester also reduced [CI-Ii, and both phorbol ester and osmotic shock were not additive, suggesting a contribution of PKC to C1exit during RVD. Patch-clamp studies revealed an increase in NP, (aggregate open probability of multiple channels in a patch) of 23/33 pS Clchannels approximately 1 min after osmotic shock, which was concurrent with the observed RVD. When H-9, an inhibitor of protein kinases, was included, NP, decreased. These observations indicate that this channel, present in rabbit proximal tubule cells, is activated during RVD through phosphorylation by PKC (Ogawa et al., 1992). Finally, a study showed that cytochalasin D, an F-actin-disrupting agent, decreases the activity of the 23-33 pS C1- channel described above (Suzuki et al., 1993). The authors concluded that cytochalasin D, by disrupting F-actin, inhibits active CI- channel as well as whole cell C1currents in rabbit proximal tubule cells (Suzuki et al., 1993).The fact that the F-actin-based cytoskeleton may regulate ion channels is an exciting observation and, indeed, several groups have provided evidence for cytoskeletal regulation of ion channels (Schwiebert et af., 1991a,b,1994; Mills et al., 1993,1994;Cantiello et af., 1993; Guharay and Sachs, 1984; Stanton etal., 1991). However, in these other studies (see below in Section IV,C) disruption of F-actin led to activation of the channel. Moreover, the 23/33 pS C1- channel has been implicated in RVD in rabbit proximal tubule cells (Ogawa et al., 1992; Suzuki et af., 1993). The fact that a swelling-activated C1- channel is inhibited by F-actin fragmentation is difficult to reconcile, since cell swelling disrupts the membrane-associated actin network. Further studies are necessary to link the protein kinaseassociated signaling mechanisms, the swelling-associated signaling mechanisms, and the F-actin-associated regulation into an integrated system of ion channel regulation. Nevertheless, this channel has provided an excellent end point for the study of cell signaling and ion channel regulation. Figure 2a illustrates a model of the mechanisms of C1- transport in the proximal tubule and depicts the stimuli which activate the C1- channels described in this section. CI- channels in the apical and basolateral membranes of rabbit proximal tubules contribute to RVD. Therefore, it is possible that each channel or both channels may respond differently or simultaneously to specific stimuli that cause RVD. C1- channels in both apical and basolateral membranes are also stimulated by the cAMP/PKA signaling pathway. Weinstein has suggested that under normal conditions of transport, apical C1- channels could be a pathway for C1- secretion. However, the role of C1- secretion on transepithelial transport or in cell homeostasis remains to be delineated (Weinstein, 1992). Clearly, further studies will be necessary to define the function of C1- channels in the proximal tubule.
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8. Chloride Transport in Thin Descending (DLH) and Thin Ascending Limbs (ALH) of Henle’s Loop
The cells of the thin descending limb of Henle’s loop are both morphologically and functionally heterogeneous (Imai et al., 1988b; Imai, 1984). The transepithelial permeability of C1- measured either in the DLH of cortical nephrons or the upper portion of DLH ofjuxtamedullary nephrons of hamster kidney varies from low to moderately permeable to C1- (Imai, 1984). Lopes ef a/. (1988) through videooptical techniques found a C1conductance that was activated by hypotonicity in the basolateral membrane of cells from the lower portion of DLH dissected from juxtamedullary nephrons. This C1- conductance is believed to be important for C1efflux during RVD. Patch-clamp studies have not been performed on cells derived from the thin descending limb. Kondo et al. (1987a,b,1988) established that the thin ascending limb of Henle’s loop in juxtamedullary nephrons displayed the highest permeability to CI- of any nephron segment. A large portion of C1- transport across the ALH in hamster is transcellular, inhibited by furosemide and by DPC o r NPPB, and dependent on intracellular pH and [Ca2+li.Yoshitomi el ul. ( 1988) measured, with intracellular microelectrodes, the transepithelial and basolateral membrane potentials during changes in luminal or basolatera1 CI - concentrations. The results showed that both luminal and basolatera1 membranes are conductive to CI- (Yoshitomi et a/., 1988), although the basolateral membrane C1- conductance was larger. The basolateral CI- conductance is stimulated by an increase in Ca’f and inhibited by low pH. Imai e t a / . (1988a)also analyzed the effects of sulfhydryl reagents on C1- conductance in this nephron segment. They postulated that modulation of C1- conductance in this segment occurs by two distinct pathways, one stimulatory and another inhibitory both of which contain a SH groups (Imai et ul., 1988a). The exact nature of these sites is unknown. In another study, Onuchic er al. (1992), using videooptical techniques, detected a C1- conductive pathway sensitive to anthracene-9-carboxylate (9-AC), a C1- channel blocker, in the basolateral membrane of epithelia from the ALH that was activated during RVD. Additional experiments showed that depletion of K + , C1-, or Ca2+or addition of barium, 9-AC, and EGTA abolished RVD. Since RVD is abolished in the absence of Ca’+, it might be possible that aCaIi-activated C1- channel is the pathway for C1- loss during this process. Figures 2b and 2c depict models of C1- transport across apical and basolateral membranes of the DLH and ALH of Henle’s loop and how these conductances appear to be regulated. It is unclear whether the Ca2+activated Cl- conductance found by Yoshitomi et a/. and the swellingand Ca’+-activated C1- conductance characterized by Onuchic et al. are
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carried by a single CI- channel or represent multiple C1- channel subtypes. Of interest, a relative of the C1C-2 chloride channel gene, CIC-Kl, has been cloned and localized to this nephron segment. These results are discussed below.
C. Chloride Transport in the Thick Ascending Limb of Henle's Loop
The TAL of Henle's loop is responsible for 20-25% of NaCl reabsorption along the nephron (Berry and Rector, 1991; Reeves and Andreoli, 1992a). Of that quantity, 50% is absorbed via the paracellular pathway, whereas 50% is transported actively via transcellular mechanisms (Hebert and Andreoli, 1986).In studies by Andreoli and colleagues, C1- was shown to account for 90% of the equivalent short-circuit current in TAL (Hebert and Andreoli, 1984; Hebert er al., 1984). By utilizing a variety of models for the TAL, several investigators describe C1- absorption as a two-step process (Reeves and Andreoli, 1992b; Greger, 1985; Oberleitner et al., 1982; Yoshitomi et al., 1987). C1- is absorbed across the apical membrane by a furasemide-sensitive, Na+,Kt ,2C1- co-transporter. Once inside the cell, C1- exits across the basolateral membrane through a CI- channel down a favorable electrochemical gradient. A model of CI- reabsorption across the TAL is shown in Fig. 2d. The C1- channel blocker, DPC, was characterized initially as an inhibitor of C1- channels in the basolateral membrane of TAL (Distefano er al., 1985; Wangemann et al., 1986). Also involved in basolateral C1- exit is a KCI co-transporter which is thought to play only a minor role in net C1- reabsorption (Greger and Schlatter, 1983; Oberleitner et al., 1983). C1- reabsorption in the TAL is hormonally regulated. AVP, via its second-messenger CAMP,stimulates CI- reabsorption, in part, by activating the Na" ,Kt ,2C1- co-transporter in the apical membrane (Hebert and Andreoli, 1984; Hebert et al., 1984; Molony et ul., 1987). C1- absorption by the TAL is inhibited by atrial natriuretic peptide (ANP) via its second messenger, cGMP (Bailly ef al., 1992). It is unknown whether cGMP regulates the entry step or the exit step of C1- transport in the TAL. Again, both stimulatory and inhibitory pathways modulate C1- reabsorption in this segment. With the knowledge that the basolateral membrane of TAL contained CI- channels, studies were initiated to characterize the channels responsible for CI- absorption across the basolateral membrane. Despite the relative difficulty of forming gigaohm seals on the basolateral membrane of TALs due to a thick basement membrane resistant to enzymatic digestion, a handful of studies have successfully characterized Cl- channels by patch clamping cells from this nephron segment.
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Schlatter and Greger (1991). in intact TALs, and Greger et al. (1990), in isolated cells from TAL, characterized the same 31/42 pS CI- channel in the basolateral membrane. The activity of this channel increases with depolarization. Paulais and Teulon ( 1990)characterized the properties and regulation of a 40-pS CI- channel (Pc,-PNat= 20:l) in the basolateral membrane of mouse TAL. The activity of this channel was unaffected by Ca'+ or pH, but was increased with depolarization. The anion permeability sequence was Cl- > Br- > NO3 >> F- (not permeable to gluconate). Interestingly, I - blocked the channel, a property shared by other C1channels including CFTR (Cliff et al., 1992). In 8% of cell-attached and inside-out recordings from the basolateral membrane of untreated TALs, this channel was active. However, upon treatment with a cocktail containing forskolin (10 pM),8-bromo-CAMP (100 pM),and IBMX (10 p M ) , an inhibitor of cyclic nucleotide phosphodiesterases, 24% of cell-attached recordings and 67% of inside-out recordings contained active, 40-pS C1channels (Paulais and Teulon, 1990). Except for a minor difference in conductance, this channel and the one described above may represent the same channel. Nevertheless, these data show that CAMP increases CI - reabsorption across the TAL by activating the C1- channel in the basolateral membrane as well as the Na+,K',2ClV co-transporter in the apical membrane. Because the basolateral membrane of intact TALs was difficult to study by conventional patch-clamp techniques, Andreoli and co-workers developed a method of isolating basolateral membrane vesicles from rabbit outer medulla (Bayliss et al., 1990). The authors point out that this is not a pure preparation of basolateral membranes from rabbit TAL, which makes it difficult to pinpoint the precise location of the channels in vivo. Despite this caviat, this group characterized extensively the properties of CIV channels in isolated vesicles (Reeves and Andreoli, 1992b). Using a 36CI- efflux assay, Bayliss et al. (1990) showed that this channel was inhibited by DPC with an IC,,of 154 p M . The anion permeability sequence was I - > CIV 2 NO3- >> Glu-. Similar results were obtained by basolateral membrane vesicles from porcine outer medulla (Breuer, 1989). In a series of papers, Reeves, Andreoli, and colleagues characterized C1channels from membranes vesicles incorporated into lipid bilayers. The single-channel conductance in symmetrical 270 mM Cl--containing solutions is 70-90 pS. Normalization of the single-channel conductance with other studies using symmetrical 135- I45 m M CI--containing solutions yields a conductance of 35-40 pS, a conductance similar to that of channels described above in the basolateral membrane of intact TALs or isolated cells from TALs (Paulais and Teulon, 1990; Hebert and Andreoli, 1984; Greger et al., 1990). Increasing CI- concentration on the outside of the membrane increases Cl- channel activity (Winters et al., 1991).The cata-
Erik M. Schwiebert et a/. lytic subunit of PKA and ATP activates these 70- to 90-pS Cl- channels in a manner analogous to that observed when extracellular C1- concentration is increased (Winters et al., 1991). Winters et af. (1990) also found that agents which disrupt arginine and lysine residues within the channel decrease channel activity. In additional studies, they show that C1- ions themselves interact with the channel by binding to arginine and lysine residues on their positively charged side chains (Winters er af., 1992). Finally, this group has taken initial steps to obtain a cDNA for this C1channel (see Section VII, Renal Chloride Channels Biochemistry and Molecular Biology).
N. CHLORIDE TRANSPORT IN THE DISTAL NEPHRON: DISTAL CONVOLUTED TUBULE THROUGH THE COLLECTING DUCT A. Chloride Transport in the Distal Convoluted Tubule (DCT)
The DCT was originally defined as the segment which extends from the macula densa to the first confluence of nephrons (Koeppen and Stanton, 1992). However, it is clear that three distinct segments exist between the macula densa and the crotical collecting duct: ( I ) the distal convoluted tubule: (2) the connecting tubule (CNT); and (3) the initial portion of the cortical collecting duct (Koeppen and Stanton, 1992). These segments together are responsible for the reabsorption of approximately 5% of the filtered load of C1-. The separation between DCT and CNT is abrupt in the rabbit but gradual in the rat and the human (Madsen and Tisher, 1986). The entry mechanism for C1- across the apical membrane of the rat DCT involves a thiazide-sensitive NaCl co-transporter (Beaumont ef al., 1988; Beck et al., 1988; Costanzo, 1985). Friedman and colleagues, using an immortalized cell line derived from mouse DCT, have demonstrated that CI - reabsorption is a two-step process involving entry across the apical membrane via an electroneutral, thiazide-sensitive NaCl cotransporter and exit across the basolateral membrane via an NPPBsensitive C1- channel (Friedman and Gesek, 1993; Gesek and Friedman, 1993). In constrast to the rat or mouse DCT, the thiazide-sensitive NaCl co-transport system is absent from the luminal membrane of rabbit DCT (Koeppen and Stanton, 1992). A preliminary report suggests that C1entry could also occur through a thiazide-insensitive co-transport mechanism which involves formate and oxalate-coupled C1- movement ( Wang ef al., 1992,1993). C1- exit across the basolateral membrane occurs via a small C1- conductive pathway (Taniguchi et af.,1989; Yoshitomi et al., 1989b). In only one study of the single-channel properties of C1- channels
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in this segment, an 11-pS Cl--selective channel was found in the apical membrane but was not fully characterized (Taniguchi et al., 1989). A recent study confirmed the fact that a low-conductance, 9-pS chloride channel was present in primary cultures of rabbit distal convoluted bright tubule (Poncet et al., 1994). In unstimulated cells, these channels were present in 9% of cell-attached patches. However, pretreatment of cells with 5 pA4 forskolin or 1 mM 8-Br-CAMPincreased the incidence of the low-conductance channels to 26 and 37%, respectively (Poncet et a / ., 1994). Upon excision to the inside-out configuration, only 1 of 47 channels remained active, whereas addition of the catalytic subunit of protein kinase A with 2 mM ATP was necessary to restore channel activity (Poncet et ul., 1994).These 9-pS channels displayed a linear I-V relationship, appeared in patches as clusters of channels, were unaffected by depolarization or hyperpolarization, were sensitive to DPC at 1 mM but not at 100 p M , were insensitive to DNDS or NPPB, and exhibited a halide permeability sequence of Br->CI->I-(I- actually appears to block the channel)(Poncet et af., 1994). In a low percentage of patches (<3%), outwardly rectifying, 30-pS C1- channels were observed, but their regulation or biophysical properties were difficult to characterize due to a low incidence of activity (Poncet et al., 1994).These results suggest strongly that the apical surface of rabbit DCT cells contains CAMP-activated CFTR C1- channels. A summary of the studies that support the presence of CFTR C1- channels is presented at the end of this part of the review. Further studies are necessary to characterize further the functional role of CFTR in this segment. A cell model illustrating what is known about C1- transport in the rat DCT cell is shown in Fig. 3A. 8. Chloride Transport in the Connecting Tubule (CNT)
The CNT is composed of a heterogeneous population of cells (Berry and Rector, 1991; Koeppen and Stanton, 1992).Two cell types are present, CNT cells, involved primarily in Na+ reabsorption, and intercalated cells, responsible for acid-base transport. Both cell types express specific mechanisms of CI- transport. Studies have identified the rabbit CNT cell as the thiazide-sensitive segment. For example addition of the thiazide diuretic, trichloromethiazide, to the lumen reduces NaCl reabsorption by 30% and hyperpolarizes V,, of rabbit CNT cells, while rabbit DCT cells and intercalated cells were not affected by thiazides (Yoshitomi et at., 1989a).Similar results have been found in the urinary bladder of the winter flounder (Stokes, 1984) and the late distal tubule from Amphiuma (Stanton, 1988, 1990). As in DCT cells, a C1- channel plays a role in the movement of
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FIGURE 3 Cell models illustrating the mechanisms of CI- transport within the distal nephron of the kidney. For simplicity and clarity. only CI- transport mechanisms are shown.
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FIGURE 3 Continued
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FIGURE 3 Continued
C1- out of the cell across the basolateral cell membrane (Koeppen and Stanton, 1992). The single-channel characteristics of the basolateral C1channel have not been determined. A cell model of C1- transport across the rabbit CNT cell is shown in Fig. 3B.
C. Chloride Transport in the Cortical Collecting Duct (CCD)
The CCD is composed of two cell types: principal cells (PC) and intercalated cells (IC) (Kaissling and Kriz, 1979; Madsen and Tisher, 1986; Muto et al., 1990; Koeppen et al., 1983). In the CCD, principal cells comprise 60-70% of the cells, whereas intercalated cells constitute the remaining 30-40% (Lonnerholm and Ridderstrale, 1980; Muto e? af., 1990; Koeppen et af.,1983). PCs are also the predominant cell type in the CNT and the CCD (Muto et al., 1990). PC cells reabsorb Na+ and secrete K + and have C1- channels in both the apical and basolateral membranes (see below). IC cells play a role in acid base as well as CI- transport. ICs can be further subdivided into A-type ICs, cells that secrete acid, and B-type ICs which secrete bicarbonate. Cell models illustrating C1- transport pathways in PCs, A-type ICs, and B-type ICs in the rabbit are shown in Figs. 3c-3e.
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The paracellular pathway in the CCD is permeable to CI-. Consequently, as much as 80% of transepithelial C1- reabsorption takes place via the paracellular pathway driven by the lumen-negative transepithelial voltage (Schuster and Stokes, 1987; Sansom et al., 1984). The remainder of C1- reabsorption is transcellular involving specific C1- transport pathways.
1. Principal Cells (Fig. 3C) It is known that a basolateral CI- conductance participates in cell volume regulation in rabbit PCs (Strange, 1989). In contrast, an entry step for CI- in PCs is not fully understood. Evidence has been presented for the presence of a C1-IHCO; exchanger in the apical membrane in rabbit PCs (Strange, 1991; Sansom et al., 1984,1990;Koeppen et a/., 1983; Muto et al., 1990). However, in the rat, one study identified a thiazide-sensitive NaCl cotransporter in the apical membrane (Terada and Knepper, 1990). Another study concluded that rat PCs express no mechanisms for C1transport (Schlatter et at., 1990). Finally, another study (see below) has found a CI- channel in the apical membrane of rabbit PCs (Ling and Kokko, 1992). Obviously more studies are necessary to define the precise mechanism(s) of CI- entry across the apical membrane of PCs. Several patch-clamp studies succesfully characterized CI- channels in the basolateral membrane of PCs. Sansom et al. (1990) identified a “double-barreled” C1- channel in rabbit PCs that was similar to a C1channel recorded from the electric organ of Torpedo (Miller, 1982). This channel displayed two open states (0, and 0,)and, therefore, two distinct conductances of 23 pS (0,) and 46 pS (O,)(Sansom et af., 1990). The channel was not dependent upon voltage, although the open probability increased somewhat with hyperpolarization (Sansom et al., 1990). The precise physiological role of this channel or its regulation has not been elucidated. Other studies have focused on CI- conductances in the apical membrane of rabbit CCD cells grown in primary culture which displayed a PC-like phenotype. In cells treated with aldosterone, 9% of cell-attached patches contained a 9-pS C1-channel with a linear Z-V relationship (Ling and Kokko, 1992). In cell-attached patches pretreated with PGE,, however, the incidence of the 9 pS C1- channel increased to 32% (Ling and Kokko, 1992). Forskolin or permeable analogues of CAMP mimicked the effect of PGE, in increasing incidence and open probability of the channel (Ling and Kokko, 1992). Of interest, this channel is insensitive to DIDS, indicating that this channel shares many properties with CFTR C1- channels including single-channel conductance, a linear Z- V relationahip, time and voltage independence, and resistance to DIDS blockade (Ling and Kokko,
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1992; Cliff er al., 1992; Egan et al., 1992; Gray et al., 1989; Tabcharani et al., 1990). Breyer and co-workers in tubules isolated from rabbit CCD found a similar 8-pS C1- channel in the apical membrane (K. Superdock and M. Breyer, unpublished observations). Moreover, Breyer and coworkers performed RT-PCR on RNA isolated from rabbit kidney, RT-PCR and RNase protection assays on message isolated from immunodissected rabbit CCD cells, and immunoprecipitation of CFTR protein from CCD; all sets of experiments are consistent with the presence of CFTR mRNA and protein in the kidney and, specifically, in the CCD (M. Breyer, personal communication). In another preliminary report, Breyer and coworkers found an inwardly rectifying 54/22 p s C1- channel in the apical membrane of immunodissected rabbit CCD cells that was inhibited by ATP (Superdock et a / . , 1992,1993). This channel type is novel and has not been found in any other renal cell type. Finally, in a preliminary report, Korbmacher et al., (1992)found that forskolin increased the wholecell C1- conductance in a cell line from mouse CCD (Ml-CCD) approximately five-fold, consistent with more specific single-channel studies described above. However, due to the heterogeneous population of cells in the preparations used by Superdock et al. and Korbmacher et al., it is not possible to localize these channels or conductances to a specific cell type in the CCD. Taken together, these results demonstrate that specific chloride channels may be expressed on both the apical and basolateral membranes of PC cells in the CCD and are activated by cAMP/PKA signaling pathways. A similar distribution and regulation of C1- channels has been demonstrated in the proximal tubule. Further studies are necessary to define the physiological significance of cAMP/PKA-activated C1--conductive pathways in both membranes of PC cells. 2. Intercalated Cells In the B-type ICs in the CCD from the rabbit (Fig. 3D), both C1reabsorption and HCO; secretion across the apical cell membrane occurs via an electroneutral pathway (Schuster and Stokes, 1987; Muto et al., 1990; Star er al., 1985; Schuster, 1985,1986; Schwartz et al., 1985). In constrast, CI- is reabsorbed across the basolateral membrane, via a CI-conductance (Muto et al., 1990; Sansom er a/., 1984). Inhibition of this C1V conductance reduces CI- absorption and HCO; secretion in rabbit CCD by eliminating the ability of CI- to exit the cell across the basolateral cell membrane (Schuster, 1985). Currently, only one patchclamp study has been performed in a preparation of B-type IC cells to define the properties and regulation of whole-cell CI- currents. Isoprotereno1 stimulates CI currents via a P-adrenergic receptor-mediated process,
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and atenolol, a @receptor antagonist, blocks the response (Ikeda et af., 1992). Regulation of the whole-cell currents does not occur via cAMP or Ca2', but the currents are activated by GTPyS (Ikeda et af., 1992). In addition, because the effects of isoproterenol and GTPyS are additive, the authors speculate that P-adrenergic receptors stimulate basolateral CI - conductance by a direct, membrane-delimited mechanism involving a G protein (Ikeda et af., 1992). In A-type ICs from the rabbit (Fig. 3E), the H+-ATPase is located in the apical membrane and the Cl-/HCO; exchanger is expressed in the basolateral membrane. Under steady-state conditions, B-type ICs constitute most of the 30-40% of ICs in the rabbit CCD (Schwartz et af., 1985). However, when the animal is subjected to an acid load, A-type ICs increase in number at the expense of B-type ICs (Schwartz et af., 1985). In A-type ICs, there is no net transcellular C1- transport, but movement of C1- in and out of the cell across both apical and basolateral membranes does occur. Removal of CI- from the basolateral solution or inhibition of the basolateral Cl- conductance attenuates electrogenic H + secretion across the apical cell membrane CCD (Hanley et af., 1980). Thus, the basolateral C1- conductance is important for H + secretion and HCO; reabsorption to occur by allowing for C1- to recycle across the basolateral cell membrane and by providing a counter ion to balance electrogenic H + secretion. Patch-clamp studies were performed on RCCT-28A cells, an immortalized cell line derived from rabbit CCD, with properties most similar to A-type ICs (Arend et af., 1989; Schwiebert er af., 1992). In whole-cell patch recordings, the conductance of RCCT-28A cells was determined to be attributable mostly to C1- (Dietl et al., 1992). Isoproterenol, as well as cAMP analogues, stimulate an outwardly rectifying, whole-cell C1conductance (Dietl et af.,1992). In single-channel recordings of the basolateral membrane of RCCT-28A cells, 13/96 pS C1- channels were observed with an outwardly rectifying Z-V relationship (Dietl and Stanton, 1992). These channels are highly permeable to C1- compared with Na+ ( P c , - : P N a += 64:l) and were inhibited by DIDS and NPPB (Dietl and Stanton, 1992). A subset of these channels that displayed a low open probability was activated by the catalytic subunit of PKA, an effect that was reversed by alkaline phosphatase (Dietl and Stanton, 1992). In contrast, channels already activated by excision or a large depolarizing voltage pulse failed to respond to PKA (Dietl and Stanton, 1992). The authors concluded that this channel was the one regulated by isoproterenol via a second-messenger pathway involving cAMP and PKA and that this channel may be involved in C1- recycling across the basolateral membrane, by removing the C1- which enters the cell via the Cl-/HCO; exchanger in the same membrane.
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Even though intracellular microelectrode recording of ICs displays no measurable conductance for any ion in the apical membrane under steadystate conditions (Muto et af., 1990; Sansom et af., 1984; Koeppen et af., 19831, C1- channels are present. Stanton and co-workers identified a largeconductance (305-pS) C1- channel in the apical membrane of isolated rabbit CCDs, in rabbit IC cells in primary culture, and also in RCCT-28A cells (Light et al., 1990; Schwiebert et af., 1990,1992). These channels have the following characteristics: a linear I-V relationship; inactivation at voltages more negative than - 30 mV and more positive than + 30 mV; activation upon patch excision, activation by large depolarizing voltage pulses (>+50 mV); inhibition by DIDS, DPC, or NPPB; and greater permeability for C1- than HCO;, gluconate, or Na+ (Pcl-:PHCo3= 2:l; P c l - : P G I U= - 9:1;Pcl-:PN,+ = 14:l). This channel is only observed in 3% of cell-attached patches under isotonic conditions in RCCT-28A cells. However, the 305-pS channel can be observed more frequently if the bath osmolality is reduced only by about 10% (Schwiebert et af., 1994; Mills et af., 1993,1994).After 2-5 min in hypotonic solutions, the channel becomes active attaining a high open probability (B0.50) for approximately 5-10 min before closing (Schwiebert et af., 1994; Mills et af., 1993,1994). At 15 min following hypotonic challenge, channel open probability is essentially 0.00 (Schwiebert et af., 1994; Mills et al., 1993,1994). The increase in open probability correlated with RVD, suggesting that this channel may be required for RVD. Negative pressure ( - 2 to - 15 cm H,O pressure) applied to excised, inside-out patches of the apical membrane from these cells activates quiescent 305-pS channels. The negative pressure is also effective in increasing the open probability of channels spontaneously activated by patch excision (Schwiebert et af.,1994; Mills et al., 1993,1994). Both swelling- and negative pressure-induced activation of 305-pS C1- channels occurs via the filamentous actin (F-actin) cytoskeleton. Evidence for an involvement of filamentous actin comes from experiments which show that dihydrocytochalasin B (DHCB) as well as other cytochalasins (cytochalasins B and D) can activate single channels in inside-out patches. Moreover, swelling or stretch fails to stimulate single channels or whole-cell conductance in the presence of DHCB activation, indicating that disruption of F-actin was essential for mechanical activation (Schwiebert et af., 1994; Mills et al., 1993,1994). In support of the cytochalasin data, phalloidin, a mushroom toxin and F-actin-stabilizing agent, blocked the ability of swelling or stretch to stimulate the C1- channel or whole-cell C1- conductance. Preliminary studies utilizing rhodamine-phalloidin to visualize F-actin indicate that swelling or activation of protein kinase C depolymerize the F-actin cytoskeletal network in RCCT-28A cells ( J . W. Mills, E. M. Schwiebert, and B. A. Stanton, unpublished observations). Interestingly,
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swelling stimulation of whole-cell C1- conductance also required protein kinase C and a pertussis toxin (PTX)-sensitive G protein, since swellinginduced stimulation was inhibited or abolished by calphostin C, a PKC inhibitor, and PTX, an inhibitor of a subset of heterotrimeric G proteins, respectively (Schwiebert et al., 1994; Mills et al., 1993,1994). Taken together, these results suggest that the 305-ps C1- channel in RCCT-28A cells mediates, at least in part, C1- efflux during RVD and that this channel is regulated during cell swelling by a signaling pathway that involves a PTXsensitive G protein, protein kinase C, and the actin-based cytoskeleton. It is not clear whether autocoids such as adenosine (see below) are released during cell swelling and bind to receptors in an autocrine or paracrine fashion to trigger this pathway or whether cell swelling and the corresponding increase in membrane tension activate second messengers directly. The 305-pS C1- channel is also regulated by autocoids. Adenosine, via its A, receptor subtype, stimulates the 305-pS C1- channel in cell-attached patches (Schwiebert et al., 1992). Adenosine activates this channel both in cell-attached and inside-out patches via the following second-messenger pathway: binding of an agonist to an A, receptor coupled to phospholipase C, release of diacylglycerol, activation of protein kinase C, and, finally, stimulation of a PTX-sensitive G protein (Schwiebert et al., 1990,1992). Moreover, in inside-out patches treated with PTX to inhibit 305-pS CIchannels, PKC failed to activate the channels, indicating that PKC required a G protein to activate the channel (Schwiebert ef al., 1990,1992). These studies provide another example of agonist-activated conductances in the plasma membranes of renal epithelial cells where there is no macroscopic conductance for CI- or any ion detected under isotonic or steady-state conditions. Often a stimulant such as hypotonicity will activate “silent” C1- channels in cell membrane-generating macroscopic CI- conductances which are used by the cell when needed. D. Chloride Transport in the Outer Medullary Collecting Duct (OMCD) The outer stripe of the OMCD is comprised both of PCs and B-type ICs (Berry and Rector, 1991; Koeppenand Stanton, 1992; Koeppen, 1987). In constrast, the inner stripe of the OMCD (OMCD,,), is composed of Atype ICs (Koeppen and Stanton, 1992; Koeppen, 1987; Ridderstrale et al., 1988). The OMCD, secretes C1- at rates equal to that of H’ secretion (Stone et al., 1983). CI- secretion across the A-type ICs in OMCD,, occurs via the paracellular pathway. Microelectrode studies have failed to demonstrate the presence of a macroscopic CI- conductance in the apical membrane under steady-state conditions (Koeppen, 1986). How-
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ever, given that a pattern has emerged in other nephron segments where macroscopic conductances for CI- cannot be detected by approaches utilizing intracellular microelectrodes but ion channels are identified by patch clamping, it is certainly possible that the movement of CI- across the apical cell membrane could involve an apical CI- channel. A series of studies indicates that CI - channels are present in these cells. For example, Koeppen and co-workers (1991) have shown that isoproterenol, CAMP, and PKA stimulate an outwardly rectifying C1current in whole-cell recordings from cells immunodissected from rabbit OMCD,,. Concomitant operation of basolateral CI- channels, basolateral Cl-/HCO; exchangers, and apical H+-ATPase is important for properly maintaining acid-base transport across this nephron segment (Koeppen el id., 1991). These currents may be generated by outwardly rectifying CI- channels similar to the ones found in the basolateral membrane of RCCT-28A cells, A-type ICs derived from rabbit CCD (Diet1 and Stanton, 1992). Obviously, single-channel studies will be necessary to characterize the outwardly rectifying Cl- channels in OMCD,, cells and to determine their role in acid secretion. E. Chloride Transport in the Inner Medullary Collecting Duct (IMCD)
Compared to other nephron segments, comparatively less information is available about C1- transport in the IMCD. The IMCD is composed primarily of IMCD cells; only the initial portion of the IMCD (IMCD, or IMCD,) is believed to contain a low percentage of ICs (Berry and Rector, 1991; Koeppen and Stanton, 1992). As described above, PCs in the CCD are primarily responsible for Na' reabsorption, although C1- channels have been described in both membranes. Rocha and Kudo showed initially that IMCD cells possess the capacity to reabsorb Na' and secrete C1-. They showed that low concentrations of ANP reduced Na+ reabsorption, while as little as 60 pM ANP increased bath-to-lumen C1- secretion and generated a lumen-negative potential (Rocha and Kudo, 1990a,b). Rocha and Kudo concluded that ANP, via its second-messenger cGMP, stimulates CI- secretion by activating a furosemide- and bumetanide-sensitive N a + , K', 2C1- co-transporter in the basolateral membrane. Lumennegative voltages were measured in the IMCD, of Brattleboro rats with the use of isolated perfused tubules and microelectrode impalements (Stanton, 1989). Preliminary studies utilizing measurement of transepithelial short-circuit current (Zsc) generated by monolayers of immortalized mouse IMCD cells indicate that these cells are capable of Na' reabsorption and C1- secretion
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(Kizer et af., 1993; Vandorpe et af., 1993). In the presence of amiloride (10p M ) to block Na+ transport, vasopressin ( 1 nM 1, and permeable cyclic AMP analogues (100 p M CPT-CAMP)increased short-circuit current that was attributable to C1- secretion (Kizer et al., 1993). Of interest, both Nat and C1- current were enhanced by aldosterone ( 1 nM)(Kizer et af., 1993). Characterization of transepithelial C1- secretion across mouse IMCD cell monolayers showed that basolateral C1- entry was inhibited by furosemide, DIDS, or removal of HCO; from the bathing solutions, suggesting roles for Na+, K t ,2C1- co-transport and Cl-/HCO; exchange in the basolateral entry mechanism (Kizer et af., 1993). Apical C1- secretion was inhibited by 1-10 mM DPC or 100 p M glibenclamide but was unaffected by 100 pM DIDS or 100 p M NPPB, a result which suggests that C1- secretion may be mediated by CFTR C1- channel (Kizer et af., 1993; Vandorpe et af.,1993). Indeed, parallel, preliminary whole-cell patch-clamp studies indicate that CPT-CAMPincreases whole-cell chloride conductance by 100% (Vandorpe et al., 1993). These chloride currents displayed a linear I-V relationship, sensitivity to DPC, and time- and voltage-independent kinetics (Vandorpe et al., 1993). Finally, CFTR was immonolocalized to the apical region of IMCD cells in mouse kidney (Vandorpe et af.,1993). Taken together, these results are consistent with the observation by Rocha and Kudo that the IMCD reabsorbs Na+ and secretes C1- . Moreover, these results indicate that vasopressin or cyclic AMP activates secretory C1- currents that may be carried by CFTR chloride channels in the apical membrane. More studies will be necessary to examine the capacity of the IMCD cell both to absorb Naf and to secrete C1- and the cellular mechanisms which regulate each process. It is interesting to speculate that the cells which constitute the last segment of the nephron may also be the most diversified in their transport capabilities in order to define more precisely the ionic contents of the final urine. The results described in the IMCD as well as results described above in earlier nephron segments (PCT, DCT, CCD) are consistent with a published study and a preliminary study by Guggino and co-workers on the distribution of CFTR along the nephron. Crawford et al., (1991) found that CFTR was detected by immunocytochemistry in proximal and distal tubules in the outer cortex and in intracellular vesicles derived from proximal tubule. More recent preliminary studies, utilizing nested RT-PCR with two pairs of primers generated against exons 13 and 14 of the CF gene (these exons encode portions of the R domain of CFTR), indicate that CFTR is present in rat kidney, specifically within the cortex, outer medulla, and inner medulla (Morales et af., 1993). CFTR was most abundant in the cortex. RT-PCR of individually dissected segments of the rat
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nephron indicate that CFTR is present throughout the proximal tubule (S,,S2.3), in the thin limbs of Henle’s loop, in cortical and medullary TAL, in the CCD, and in the IMCD. CFTR was absent from glomeruli, a result consistent with previous studies (Morales et al., 1993). In addition to a band of the expected size for full-length CFTR, a smaller band was also found using nested RT-PCR under identical conditions and may represent a splice variant of CFTR. This smaller band of CFTR was most abundant in outer medulla and inner medulla and, specifically, in OMCD, in descending thin limbs of Henle’s loop, and in IMCD (Morales et al., 1993). Taken together, functional studies as well as immunocytochemical and molecular genetic analysis along the nephron have revealed an unexpected abundance and a broad distribution of CFTR in the kidney. Future studies are critical to defining the distribution, regulation, and functional role of CFTR in the kidney. A perplexing question lies in the knowledge that CFTR is abundant in kidney, while the pathophysiology associated with cystic fibrosis is subtle and not readily observed in the kidneys of CF patients. V. CHLORIDE TRANSPORT IN CULTURED CELL MODELS OF RENAL
ION TRANSPORT Several tissue culture cell models have been developed over the past several years. The ones described below have been used extensively to study renal transport mechanisms. Although the exact location in the kidney from which they were derived is not known, these models have provided much information regarding general mechanisms and types of regulation of CI- transporters and, thus, are a valuable tool. A. Xenopus Kidney Cell Line (A6) The A6 cell line has been used extensively by electrophysiologists as a model for renal “distal nephron” transport. The cells are particularly useful because they form tight, confluent monolayers. Several studies have described mechanisms of C1- transport in or across these cells. For example, two groups have characterized C1- secretion across A6 cell monolayers as a two-step process involving an Na+,K+,2C1- cotransporter in the basolateral membrane and an NPPB-sensitive CI- channel in the apical membrane (Chalfant er a[., 1992; Middleton el al., 1992). Chalfant et al. (1992) showed that AVP stimulated C1- secretion across monolayers of A6 cells, whereas Middleton et al. (1992) showed that adenosine and ATP via A2 adenosine and P2 purinergic receptors, respectively, stimulated CI- secretion by increasing intracellular CAMP.
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Several laboratories have characterized C1- channels in the apical membrane of A6 epithelial cells. Marunaka and Eaton (1990a) found a 1- to 2-pS CI- channel with a linear Z-V relationship and a dependency on bath calcium. The incidence of this channel in cell-attached patches was increased by insulin, and the channel was inhibited by alkaline phosphatases in inside-out patches (Marunaka and Eaton, 1990b). The precise physiological role of this channel is unknown. Ling and co-workers (1992a) described an 8-pS CI- channel in the apical membrane of A6 cells that was similar to the one in the apical membrane of rabbit PC cells from the CCD. This channel was stimulated within 1 min by PGE,, forskolin, and arginine vasotocin, agonists that increase intracellular CAMP (Ling el al., 1992a). The channels remained active after stimulation for as long as 45 min. The authors concluded that this channel is the one which generates the amiloride-insensitive short-circuit current observed in Ussing chamber experiments (Ling et al., 1992a). Finally, Nelson et al. (1984) described a 360-pS CI- channel in the plasma membrane of nonconfluent A6 cells. This channel is inhibited by SITS, has a linear Z-V relationship, is more permeable to CI- than Na+ (Pc,-:P,,+ = 9:1), and inactivates at a holding potential more negative than -20 mV and more positive than +20 mV (Nelson et al., 1984). This channel has similar properties to one described in the apical membrane of RCCT-28A cells (Light et al., 1990).Taken together, these data indicate that C1- channels in A6 epithelial cells have properties and mechanisms of regulation similar to those in native renal epithelia. Moreover, the type of transporters and channels described suggest that the A6 cells may be a “hybrid cell” which has transporters and channels found in multiple collecting duct cell types including prinicpal cells, intercalated cells, and IMCD cells. B. Madin-Darby Canine Kidney Cell Line (MDCK)
Several studies have examined the mechanisms of C1- transport in another commonly used distal nephron cell model, the MDCK cell line. MDCK cell express an array of ion channels, including C1- channels (Lang e f al., 1990). Several years ago, investigators examined C1- conductances involved in cell volume regulation in this cell line. Kolb et al. (1985) identified a456-pS C1- channel in the apical membrane of confluent MDCK cells at 37°C. This channel was rarely observed in cell-attached patches but its incidence was increased upon excision to the inside-out configuration (Kolb et al., 1985). It was hypothesized then that this channel could mediate C1- efflux during cell volume regulation. Indeed, Schwiebert et
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al., 1993,1994) in RCCT-2XA cells, demonstrated that a similar large conductance C1- channel was activated by cell swelling. In a report, Winters et al. showed that mastoparan, a peptide from bee and wasp venom which activates heterotrimeric G proteins by mimicking the sequence in G protein, coupled hormone receptors for G protein interaction and activation, and GTP activated CI- and K’ conductances in MDCK cells. The subsequent increase in CI- and K + permeability led to a decrease in cell volume. Similar results were found by Mills and Lubin, but these investigators used cytochalasins to activate C1- and K + channels in MDCK cells (Mills, 1987; Mills and Lubin, 1986). In a review, Simmons (1993) describes the MDCK cell as an important cellular model for C1- secretion. CI- secretion across MDCK cell monolayers is a two-step process reminiscent of that which occurs across the IMCD cell (Simmons, 1993). C1- enters across the basolateral membrane via a N a + , K + ,2C1- co-transporter and exits across the apical membrane via a CI- channel (Simmons, 1993). The exact nature of the channel responsible for CI - secretion is not known; however, CAMP-activated CI- secretion is inhibited by NPPB and by DPC but not by DIDS or other stilbene derivatives (Simmons, 1993). Volume-activated C1- channels are present in the basolateral membrane of MDCK cells and are inhibited by DIDS (Simmons, 1993). Indeed, a novel CI- channel gene was cloned from MDCK cell messenger RNA (see below). Taken together, these studies show that MDCK cells are an important model for many mechanisms of ion transport, specifically C1- secretion, and for mechanisms of regulatory volume decrease which involve CIand K’ channels. Like the A6 cell, the MDCK cell is a useful model since it grows into confluent, tight monolayers and because these cells display a “hybrid collecting duct” cell-like complement of ion transporters and channels. cil. (1994; Mills ef
VI. CHLORIDE CHANNELS IN INTRACELLULAR COMPARTMENTS
CI- channels play an important role in CIAmovement across intracellular compartments such as endosomes, Iysosomes, and the trans-Golgi network. In these organelles, CI- channels are important to compensate for positive charge produced by the electrogenic H+-ATPase pump during proton influx and to allow the intraorganelle compartment to be acidified by the net influx of HCI (Mellman er al., 1986; Rudnick, 1986). Several studies have confirmed the presence of a CI- conductance in renal endosomes. For example, Hilden showed that a small CI- conductance is
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present in rabbit renal cortex endosomes and is increased after addition of ATP (Hilden et al., 1988). These results support the idea that ATP hydrolysis induces both H translocation and C1- channel activation. Similarly, Bae and Verkman ( 1990)found a C1- conductance in endosomes from rabbit proximal tubules. This conductance is activated by protein kinase A, inhibited by phosphatases, and inhibited by DNDS (Bae and Verkman, 1990). Taken together, these studies established the presence and the importance of C1- channels in intraorganelle compartments. To determine the characteristics of the C1- channels that underlie the C1- conductance found in renal endosomes, Schmid et al. (1989) used the patch-clamp technique to describe a C1- channel in an enriched endosomal vesicle preparation from rat kidney cortex. They found a channel with a linear I-V relationship and a single-channel conductance of 73 pS in symmetrical 140 mM KCl solutions. In contrast to the ATP-sensitive channel described above, the activity of this channel is independent of ATP or changes in pH. This channel was selective for anions over cations with an anion permeability sequence of C1- = Br- = I->SOi- = F. DIDS and NPPB completely inhibits channel activity. The authors speculate that the channel is responsible for the maintenance of electroneutrality during H + uptake into endocytic vesicles. A novel C1- channel with a conductance of 115 pS in 0.41:0.15 M KCl solutions was characterized in vesicles from renal cortex (Reeves and Gurich, 1992).The authors identified three characteristics of their channel that differ from those involved in endosomal acidification: the 115-pS channel (1) is sensitive to the Cl- channel blocker IAA-94; (2) is Ca’+ activated; and (3) is not activated by PKA or inactivated by alkaline phosphatase. Thus, the newly described channel is not the channel responsible for charge compensation during endosomal acidification. Its physiological role, so far, is unknown. Taken together with the results above, multiple types of C1- channels clearly exist within vesicles and acidified organelles. However, it is possible that C1- channels normally present and functional in the plasma membrane may contaminate these vesicle preparations, particularly in endosoma1 vesicle fractions, and may cloud the study of vesiclar C1- channels which participate in vesicle acidification. Alternatively, since all plasma membrane C1- channel proteins reside in intracellular vesicles for a portion of their existence within epithelial cells, some C1- channels may participate in vesicle acidification when located intracellularly and in plasma membrane C1- movement when located on the cell surface. Future studies and better fractionation techniques need to be developed to address these questions. +
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WI. RENAL CHLORIDE CHANNEL BIOCHEMISTRY AND MOLECULAR BIOLOGY Three groups have used expression and homology cloning approaches to isolate genes which encode C1- channels (Thiemann et al., 1992; Paulmichl et al., 1992). Jentsch and colleagues, by using a homology cloning approach with cDNA probes from ClC-0 and CIC-I (cDNAs cloned from Torpedo electric organ and skeletal muscle, respective1y))Jentsch et al., 1990; Steinmeyer et al., 1991), cloned a third type of CI- channel cDNA (Thiemann et al., 1992). This channel gene appears to be ubiquitously expressed; 3.3-kb mRNA was detected in several tissues which encoded for a 99-kDa protein, and a larger 4.5-kb species was observed in an African green monkey kidney cell line (BSC-I), an SV-40 transformed monkey kidney cell line (COS-7), and a porcine kidney cell line (LLCPK,)(Thiemann et al., 1992). When this cDNA was expressed in Xenopus oocytes, a whole-cell current was recorded that was quite low and was time and voltage independent between holding potentials of - 100 to + 100 mV. However, the current was markedly activated at hyperpolarizing potentials more negative than - 100 mV. This current was inhibited by 9-AC and by DPC and was insensitive to DIDS, and the anion selectivity sequence was calculated to be CI- = Br->I- (Thiemann et al., 1992). More recent studies have shown that this channel, when expressed in Xenopus oocytes, is activated by cell swelling (Grunder et al., 1992) (See also Chapter 2 by Jentsch and colleagues in this volume). Unfortunately, single-channel analysis has also not been performed on cells expressing this cDNA. I-V plots in excised, inside-out patches are normally constructed between - 100 and + 100 mV. In order to study this channel electrophysiologically, the range of holding potentials should be widened to record CIC-2 channel activity. These studies will require very high resistance seals (in excess of 10 GR or more) to maintain the insideout configuration at such large potentials, Since this channel is expressed in several cell lines derived from kidney, future studies on CI- channels in renal epithelial cells should be performed in order to determine whether this channel is expressed. So far, studies have not been undertaken to define the relative distribution and expression of CIC-2 along the nephron. Moreover, the role of this channel in renal C1- transport is not known. Clapham and co-workers utilized expression cloning inXenopus oocytes with mRNA derived from MDCK cells to clone a C1- channel cDNA (Paulmichl et al., 1992). When this cDNA was used to probe Northern blots, a 1.8-kb mRNA was recognized that encodes for a 26-kDa protein (Paulmichl et al., 1992). CI- currents generated by expressing the RNA
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encoding this channel in Xenopus oocytes have the following characteristics: (1) inhibition by NPPB and DIDS; (2) insensitivity to [Ca”]; and (3) an outwardly rectifying I-V relationship with inactivation at depolarizing voltages (Paulmichl et al., 1992). Of interest, this channel was inhibited by varying amounts by nucleotides such as AMP, ADP, ATP, GTP, CAMP, ITP, and cGMP (CAMP and cGMP were the most potent) (Paulmichl et ul., 1992). Since this channel was cloned with message derived from a canine kidney cell line, future studies are necessary to determine which cell types along the nephron express this new CI- channel. Like C1C-2, the contribution of this channel to renal C1- transport is not understood. A new study by this group has since revealed that this gene encodes a swelling-activated chloride channel regulator which is linked to the actin cytoskeleton. Uchida et al. (1993) used RT-PCR techniques and obtained a probe based on conserved regions of the genes cloned by Jentsch and co-workers to screen the rat whole kidney cDNA library. This group isolated a cDNA clone (CIC-KI) of approximately 2.4 kb in length with a single long open reading frame of 1965 bp encoding 686 amino acids. They found 40% amino acid identity with the Cl- channel cloned from Torpedo marmorara. Hydropathy analysis demonstrated a profile very similar to those of the previously cloned C1- channels by Jentsch and colleagues, suggesting that CIC-Kl is a member of the CI- channel family. RT-PCR using microdissected nephron segments revealed that the main site of expression in the medulla was the thin ascending limb of Henle’s loop, the nephron segment which displays the highest permeability to C1- ; however. expression of CIC-Kl mRNA was observed in thin descending limb, cortical collecting duct, and inner medullary collecting duct as well. As for ClC-1 and CIC2, cRNA from CIC-Kl failed to express a C1- current in Xenopus oocytes, unless the 5’-untranslated region was replaced by the sequence found in ClC-0. With this modification, large, time-dependent C1- currents were observed, but their characteristics were quite different from those found in the other C1C channels. ClC-K 1-expressed currents displayed outward rectification, time-dependent activation at depolarizing voltages, and inhibition by DIDS and DPC which was complete at a concentration of 1 m M for each blocker. Finally, the mRNA for CIC-Kl was upregulated by dehydration, suggesting that this channel’s principal functional role may be in the renal urinary concentration mechanisms. Several investigators have isolated putative C1- channel proteins or partial cDNAs thought to encode for C1- channels (Redhead et al., 1992; Tsai el al., 1991; Zimniak et ul., 1992; Uchida et al., 1992; Schuster and Bao, 1992). Using a Cl- channel blocker, IAA-94, as a ligand in an affinity column, four major proteins were purified from membranes isolated from
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membrane vesicles derived from renal cortex and trachea (Landry et al., 1987.1989). Antibodies were generated to the 64-kDa protein, and this antibody depleted IAA-94-inhibitable CI- channel activity in solbilized kidney membranes (Redhead et al., 1992). As described above, Bae and Verkman (1990) showed that endosomes from proximal tubule contain a chloride conductance that is activated by PKA. More recent studies by Reenstra et ul. ( 1992) indicate that a single protein is a substrate for PKA in these endosomes and that has a molecular weight of 66 kDa. The antibody to the 64-kDa protein labels the apical surface of CFPAC-1 cells, cells isolated from the pancreas of a CF patient (Redhead et al., 1992). The authors conclude from these studies that this 64-kDa protein is a component or subunit of C l channels ~ present in epithelial plasma membrane and the membranes of intracellular organelles. Finn and colleagues generated a monoclonal antibody (E12) which inhibits CI - conductances in several cell types inciuding Necturus gallbladder, toad gallbladder, rat colon, and human nasal epithelia (Tsai ef al., 1991). In Western blots, this antibody recognizes a 200- 220-kDa protein in whole cell lysates from Necturus gallbladder, toad gallbladder, urinary bladder, small intestine, A6 cells, rat colon, rabbit gastric mucosa, human lymphocytes, and human nasal epithelia (Tsai et al., 1991). Following extensive purification and reconstitution into planar lipid bilayers suggests that it is a CI- channel with a unitary conductance of 62 pS in assymetrical 1501 50 mM NaCl solutions (Tsai et ul., 1991).The gating characteristics show that the channel behaves as an independent channel or as aggregates of several channels (Tsai et al., 1991). As with the 64-kDa protein described above, the authors conclude that the 200- 220-kDa protein, expressed in a wide variety of epithelial tissues, is a component of an epithelial CIchannel. In order to determine definitively whether these proteins are subunits of CI- channels, future studies are necessary to show that these proteins affect directly the function of other proteins known to form the conductive pore of a CI- channel. Several initial preliminary reports also indicate that progress is being made toward cloning novel CI- channel genes. The polymerase chain reaction was employed to identify C1- channel genes homologous to the channels identified by Jentsch and colleagues. A PCR product was identified which has 88% nucleotide identify and 50-75% amino acid identity with CIC-2 and ClC-0, genes identified by Jentsch and co-workers (1990). A riboprobe generated from the PCR product recognized mRNA species of -5 kb in cortex and inner medulla and -5 and 9 kb in outer medulla and a cell line from rabbit cortical collecting duct (RCSV3). Using expression cloning in Xenopus oocytes, Zimniak et al. (1992) have identified a specific fraction of messenger RNA (mRNA) isolated
TABLE 1 Chloride Channels Characterized in the Kidney Blockers
Anion selectivity
OR
-
-
Regulation
Membrane
Mesangial cell (rat) PT (Ambysfornu)
Cell
4 PS
BLM
10 p s
L
DPC
PT (rabbit or Rum) I T (rabbit) TAL (rabbit) TAL (mouse)
BLM
2.5-30 pS
L
DPC
APM BLM
23/33 pS 31/42 pS
OR OR
DPC.9-AC
CI > Na
Depolarization ( + )
BLM
40 pS
L
DPC
CI > Br > NO, > F >> I,Na
CAMP ( + )
L
DPC
I > CI
cAMP/PKA ( + )
L
DPC
CI > I >> Glu. Na
TAL (rabbit)
BLMV
DCT (rabbit)
APM
Conductance ( 7 )
I-V
Cell type (species)
70-90 pS (sym. 270 CI) 9 PS
Insulin, angiotensin 11. Ca’:
I > Br > CI >> F > Asp CI = Na = K
cAMP/PKA ( + )
CI > Na
PTH,PKA,PKC,F-actin ( + )
2
NO, > GIU
Depolarization, stretch ( + )
cAMP/PKA ( + )
(+)
CCD,PC (rabbit)
BLM
23 and 46 pS
L L
DlDS
CI > Na
Hyperpolarization ( + )
CCD. PC (rabbit)
APM
CI > Na
PGE2, CAMP ( + )
BLM
9 PS 13/96 pS
DPC
CCD. A-IC (rabbit)
OR
DIDS. NPPB
CI >>> Na
Iso. CAMP. PKA
CCD. A-IC (rabbit)
APM
305 pS
L
DPC, DIDS, N PPB
CI > HCOj > Glu > Na
Swelling, stretch ( + )
CCD (rabbit)
APM
54-22 pS
IR
CI > NA
ATP,GTP,ATPyS,GTPyS ( - )
A6 (Xenopus)
APM
1-2 p s
A6 (Xenoprts)
APM
MDCK (Dog)
Cell APM
8 PS 360 p s
L L L L
MDCK (Dog)
456 pS
-
Ado, PKC, G,, F-actin (- ) PKA (NE)
(
( +)
+)
DPC. DlDS
CI > Na
PKA ( + ), Phosphatases ( - )
DPC
C1 > I >> Na
PGE2, CAMP, AVT
SITS
CI > Na
DlDS
C1> Na
(
+)
Each channel is discussed in detail in the text and appropriate references are cited. All studies used approximately 130-150 mM symmetrical CI--containing solutions unless otherwise noted. L. linear I-V relationship: OR. outwardly rectifying I-V relationship; 1R. inwardly rectifying I-V relationship: BLM. basolateral membrane; and APM. apical membrane. ( + ) activation. ( - ) inhibition. ( N E ) “no effect.” Single-channel conductance ( y ) is included.
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Erik M. Schwiebert e l al.
from medullary TALs that express a DPC-inhibitable Cl - conductance. In water-injected oocytes, the Cl- conductance was 1.43 2 0.15 pS, whereas injection of 1.8through 3.2 kb mRNA induced a C1- conductance of 9.05 5 1.56 pS. This fraction of mRNA was used to make a cDNA library with which to clone a full-length cDNA that encodes this CIchannel (Zimniak et al., 1992). Finally, a group has succeeded in cloning a gene for the thiazidesensitive NaCl co-transporter from winter flounder urinary bladder (Gamba el al., 1993). The gene predicts a 112-kDa protein with 12 membrane-spanning segments (Gamba et al., 1993).Two species of mRNA were observed routinely, a 3.7-kb mRNA in urinary bladder and a 3.0-kb mRNA in nonbladder tissues including distal tubule of the kidney (Gamba et al., 1993). This gene is the first of several genes to be isolated in the near future that encode for C1- transporters. Taken together, these published studies and studies in progress are identifying several C1- channel genes that are expressed along the nephron. In the next few years, a family or multile families of CI- channel and C1- transporter genes are likely to emerge from these projects. With this information, much analysis will be needed to elucidate the expression and functional role of these channels along the nephron. VIII. SUMMARY Table I provides a summary of C1- channels characterized by singlechannel patch-clamp methods in specialized cells associated with the glomerulus, in epithelial cells along the entire length of the nephron, and in cell lines used as models of renal epithelial CI- transport. It is clearly evident from this review that although many studies have characterized the properties of individual channels along the nephron, the distribution, the functional roles, the regulation, and the molecular properties of CIchannels in the kidney are still not understood. A possible reason for this is that C1--conductive pathways are often silent under basal conditions and require specific stimuli to become active. Moreover, more attention has been paid to cation transport in the kidney, specifically sodium and potassium. Analysis of ionic currents in renal epithelial cells along the nephron in the presence of hormones which elevate cyclic AMP, cyclic GMP, or Ca2+,or during cell swelling, should reveal novel C1--conductive pathways. The recent explosion of C1- channel molecular biology should also accelerate our knowledge of C1- channel biology in renal epithelial cells. Many exciting answers should be discovered in the near future, some of which are (1) the functional role(s) and distribution of CFTR in the kidney; (2) the function and distribution of the ClC-2 channel, the
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305
novel C1- channel gene cloned by Clapham and co-workers (Paulmichl er ui., 19921, and the most recent channel gene (CIC-KI) cloned by Uchida et al. in the kidney: (3) the physiology and pathophysiology of CI- secretion along the nephron; and (4) the identification and characterization of as yet unidentified C1- channels which underlie CI- conductances in macula densa cells, cells of the thin loops of Henle, distal convoluted tubule cells, and connecting tubule cells.
Acknowledgments We thank Dr. Matthew Breyer and Dr. Bruce Stanton for valuable comments and criticism of this review.
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CHAPTER 11 Chloride Ion Channels in Mammalian Heart Cells Tzyh-Chang Hwang and David C. Gadsby Laboratory of CardiadMernbrane Physiology, The Rockefeller University, New York. New York 10021
I . Introduction and Overview 11. PKA-Regulated CI- Channels (CFTR)
111. 1V. V. VI.
A . Regional Localization within the Heart B. Whole-Cell Studies C. Single-Channel Current Studies D. SummaryiSynthesis of Regulatory and Gating Mechanisms E. Functional Role and Cardiological Significance Stretch-Activated CI- Channels Ca?+-ActivatedCI- Channels Other CI Channels Summary and Outlook References
1. INTRODUCTION AND OVERVIEW
For the past 3 decades, cellular cardiac electrophysiological studies have been focused mainly on voltage-gated cation channels, so that our understanding of cardiac anion channels has been left lagging far behind. Fortunately, an explosion of interest in, and information about, cardiac CI- channels over the past 3 years now promises to redress this imbalance. Whereas, until recently, the very existence of any cardiac C1- channel was controversial, there is now strong electrophysiological evidence for at least three kinds of cardiac CI- channels, and molecular biological evidence suggests that there could be at least two more. Citrrenr Topic \ in Membranes. Volirnir 42 Copyright 0 1994 by AcddernK Press. Inc. All rights of reproduction in any form reserved.
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The earliest investigations of anion-conductive pathways were carried out on multicellular preparations of sheep Purkinje fibers by Carmeliet (1961) and dog and sheep Purkinje fibers by Hutter and Noble (1961), and both demonstrated that replacement of external C1- ions with larger, lesspermeant anions (like acetylglycinate, pyroglutamate, or methylsulfate) prolonged the action potential while anions like I - , NO3-, and Br- reduced the action potential duration and slowed spontaneous activity, consistent with their being more permeant. These studies indicated that C1ions make a significant contribution to action potential repolarization, and play some small role in diastolic depolarization, and suggested an anion permeability sequence for the latter effect of I- > NO,- > Br- > C1(the reverse of that for skeletal muscle; Hutter and Padsha, 1959). Later work, using Purkinje fibers voltage clamped with two microelectrodes, demonstrated that a transient outward current elicited by strong depolarization was diminished by external C1- replacement with acetylglycinate, implying that C1- ions normally carry that current (Dude1 et al., 1967). Although interpretation of these early observations on C1- ion replacement was later found to be complicated by Ca2 -chelating properties of some of the substitute anions, and hence inadvertent modulation of the extracellular free [Ca*+](Kenyon and Gibbons, 19771, careful measurements did eventually provide strong support for a [Cl-]-sensitive component of the transient outward current as well as for an additional, substantial portion carried by K+ (Kenyon and Gibbons, 1979). Cardiac C1- currents subsequently attracted relatively little attention until recently when three groups (Harvey and Hume, 1989; Bahinski et al., 1989a; Matsuoka et al., 1990), all using the whole-cell current-recording technique in mammalian cardiac myocytes, independently obtained convincing evidence for the existence of a C1- current regulated by CAMP-dependent protein kinase (PKA). Ehara and Ishihara (1990) soon recorded the underlying anion-selective single-channel currents in intact myocytes exposed to epinephrine, and unitary channel currents have since been studied in excised inside-out (Nagel et al., 1992) and outside-out Ehara and Matsuura, 1993) patches. As a result of the ensuing flurry of investigation, three different types of C1- conductance in cardiac myocytes have now been reasonably well characterized electrophysiologically, namely, that regulated by PKA (Harvey and Hume, 1989; Bahinski et al., 1989a; Matsuoka et d., 1990), another induced by cell swelling (Tseng, 1992; Sorota, 1992; Hagiwara et al., 1992b), and a third activated by a rise in intracellular free [Ca2+l (Zygmunt and Gibbons, 1991, 1992).There are already preliminary reports of unitary currents for the latter two types of CI- channel (Hagiwara et ul., 1992a; Zhang et al., 1992; Zygmunt and Gibbons, 1993). Stimulation of purinergic receptors has also been reported to activate a cardiac C1+
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conductance (Matsuura and Ehara, 1992; cf. Scamps and Vassort, 1990) as has presumed activation of protein kinase C (Walsh, 1991; Zhang and Ten Eick, 1993), but these CI- conductances are not yet fully characterized; nor are the extremely large conductance anion channels found in neonatal rat cardiac myocytes (Coulombe et al., 1987). Molecular cloning technology has similarly begun to uncover potential cardiac CI- channel molecules (e.g., Paulmichl et al., 1992; Thiemann et al., 1992; Moorman et al., 1992), although their electrophysiological properties when expressed in myocytes remain uncertain. In this review, we emphasize the latest developments contributing to our understanding of the distribution, regulation, biophysical characteristics, and functions of the various cardiac C1- channel types, in an attempt to minimize duplication with recent comprehensive reviews of this subject (Hume and Harvey, 1992; Ackerman and Clapham, 1993). II. PKA-REGULATED CI- CHANNELS (CFTR)
Given the years of relative uncertainty surrounding cardiac C1- currents, it may seem ironic that the PKA-regulated C1- conductance, now the most completely characterized of the C1- conductances in heart, was first identified in guinea pig ventricular myocytes as a Na+-sensitive pathway (Egan et a / . , 1987,1988): in myocytes impaled with single, highresistance, KCI-filled microelectrodes connected to a switch-clamp amplifier, isoproterenol (Iso) was found to activate an inward current near the normal resting potential (-80 mV) that was absent when all external Na+ ions were replaced by tetramethylammonium (TMA+)ions. This, coupled with insensitivity to standard maneuvers for reducing K + or Ca2+channel, hyperpolarization-activated or N a + / K + pump currents, and the negligible influence on the inward current of C1; replacement with isethionate- ions, led to the suggestion that Na+ ions might carry the inward current (Egan et al., 1987,1988). Convincing evidence was presented for activation of the inward current via the adenylyl cyclase/cAMP pathway (Egan et al., 1987,1988). Subsequent experiments, such as that in Fig. 1 , using the tight-seal whole-cell current-recording technique have clearly established C1- ions as the charge carrier for this current (Harvey and Hume, 1989; Bahinski eta/., 1989a; Matsuoka et a/., 1990), accounting for its insensitivity to most of the challenges tested by Egan et al. (1987,1988;the sensitivity to external N a + ions is discussed below); since inwardC1- current reflects C1- efjux, at sufficiently negative potentials Cl- current is not expected to be diminished (and could even be enhanced) by substitution of isethionate- for C1;.
Tzyh-Chang Hwang and David C. Gadsby
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FIGURE 1 A time- and voltage-independent CI- conductance activated by isoproterenol (Iso). Chart recording of membrane potential (top) and whole-cell current (A). superimposed records of whole-cell currents for pulses to t 100. t60.and t 2 O mV, from the 0-mV holding potential. in the presence or absence of isoproterenol under conditions of approximately symmetrical or asymmetrical C1- concentrations (B), and steady-state I-V relationships of whole-cell current (C) or isoproterenol-activated difference current (D). (From Bahinski et a / . , 1989a. with permission.)
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Dialysis of the cell contents against the pipette solution during wholecell current recording has been exploited to demonstrate that, like the cystic fibrosis (CF) transmembrane conductance regulator (CFTR, the epithelial Cl- channels whose dysfunction is believed responsible for CF; e.g., Collins, 1992;Welsh er al., 1992),this CI- conductance is activated by PKA-dependent phosphorylation following activation of P-adrenoceptors, G, proteins, and adenylyl cyclase (evidence reviewed below). Identity of these cardiac PKA-regulated C1- channels and CFTR is strongly suggested by their common biochemical and biophysical characteristics, determined in both whole-cell and single-channel current experiments (below). Further evidence comes from the demonstration, by Northern analysis (Fig. 21, that CFTR mRNA exists in guinea pig and rabbit ventricle and human atrium (Levesque et af.,1992; Nagel et af., 1992). Although the complete amino acid sequence of cardiac CFTR is not yet available, preliminary results using the polymerase chain reaction technique indicate extremely high homology between rabbit cardiac CFTR and human epithelial CFTR (e.g., 98% identity over a 180-amino acid stretch corresponding to the first nucleotide binding domain, NBDI; Levesque et af., 19921, at least throughout the 12 putative membrane-spanning regions (Horowitz et al., 1993). The most recent evidence suggests that the major difference between rabbit cardiac (Horowitz er d . ,1993)and human epithelial (Riordan et al., 1989) CFTR is that the former lacks 30 amino acids from the predicted first cytoplasmic loop; those residues are encoded by exon 5 of the CFTR gene. The implication is that cardiac CFTR might be an alternatively spliced isoform (Horowitz er af.,1993). A. Regional Localization within the Heart
Mechanically the heart behaves as a syncytium, but cardiac myocytes are differentiated into several types each displaying a particular set of excitability properties, determined by the relative densities of the various ion channels. A striking example is the virtually exclusive localization to atrial and nodal cells of the K' channels that are opened by stimulation of muscarinic receptors. As a result, parasympathetic stimulation affects the electrical activity of atrial and ventricular cells quite differently, strongly hyperpolarizing sinoatrial (SA) nodal cells and thereby lowering the heart rate (negative chronotropic effect), but having little influence on the membrane potential of ventricular cells during diastole. Ventricular myocytes do not lack muscarinic receptors, however, and under appropriate conditions their stimulation can inhibit adenylyl cyclase, lowering the cellular [CAMP] and hence PKA activity which, in turn, decreases
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FIGURE 2 Northern analysis of mRNA isolated from four different species (A), or of total RNA from guinea pig brain, heart, and lung (B). Blots were probed with the polymerase chain reaction amplification product corresponding to 550 bp encoding the first nucleotide binding domain of CFTR from rabbit ventricle (A) (from Levesque et al., 1992, with permission) or with the antisense RNA transcribed from the full-length human CFTR clone (B) (from Nagel et al.. 1992, with permission).
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CaZf current, leading to a reduction of action potential amplitude and duration. By analogy, a full understanding of the physiological role of PKA-regulated CI- channels therefore requires, among other things, information on their regional distribution within the heart. Takano and Noma (1992) examined the density of the catecholamineinduced CI- current in cells isolated from the SA node, atrium, and ventricle of rabbit heart: in none of the 20 nodal cells or 20 atrial cells they examined did Is0 activate any CI- current, despite the fact that it consistently enhanced hyperpolarization-activated current in SA nodal cells and L-type Ca2' current in atrial cells. Hagiwara er al. (1992b) similarly reported no activation of C1- current by Is0 or forskolin in either SA nodal or atrial cells of the rabbit. On the other hand, Harvey and Hume (1989) mentioned observing the catecholamine-induced C1- current in guinea pig atrial cells, whereas Matsuura and Ehara (1992) found that P-adrenergic stimulation activated the C1- conductance in only -10% of guinea pig atrial cells, and Horowitz er al. (1993) found no Iso-induced C1- current in either guinea pig or dog atrial myocytes. In ventricular myocytes from guinea pig (e.g., Egan et al., 1987, 1988; Harvey and Hume, 1989; Bahinski et af., 1989a; Matsuoka et al., 19901, rabbit (Harvey and Hume, 1989;Takano and Noma, 1992),and cat (Zhang and Ten Eick, 1993), but not dog (Sorota et al., 1991) or rat (Dukes et al., 1990), Is0 does activate robust CI- currents which, in rabbit ventricle, are twofold larger in myocytes isolated from the epicardial side than in those from the endocardial side (Takano and Noma, 1992). Takano and Noma (1992) noted activation of the C1- conductance by Is0 in every (240) rabbit ventricular myocyte examined, and Hwang et al. (1992a) found that 1 pM Is0 elicited PKA-regulated C1- current (-1 pAIpF at 0 mV) in 79 of 95 (83%) guinea pig ventricular myocytes (with 100 pM pipette [GTP]). Correspondingly, Northern analysis reveals expression of CFTR in guinea pig and rabbit ventricle, but not in dog ventricle or in dog, rabbit, or guinea pig atrium (Horowitz et al., 1993). The questionable presence of this Cl- conductance in atrial cells (Matsuura and Ehara, 1992; Takano and Noma, 1992; Hagiwara et al., 1992b) and its absence from SA nodal cells (Takano and Noma, 1992; Hagiwara et a f . , 1992b) argue that it can play little role in the positive chronotropic effect of catecholamines (Takano and Noma, 1992), whereas the higher density of activated C1- current in epicardial than in endocardial myocytes might be able to account, at least partly, for the shorter action potential duration of epicardial cells (Takano and Noma, 1992). However, that would require significant basal activation of the PKA-regulated C1- conductance (in the absence of adrenergic stimulation), which has not been examined in intact cardiac tissue but which has been found lacking in
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voltage-clamped internally dialyzed ventricular myocytes (Fig. 1; Bahinski et al., 1989a; Harvey er al., 1990; Hwang et al.. 1992a), possibly because diffusion from cell to pipette lowers the intracellular [CAMP](Hwang el ul., 1992a). Given the relative scarcity of PKA-regulated C1- conductance in guinea pig, rabbit, and dog atrial myocytes, and yet the positive Northern blot of human atrial mRNA (Fig. 2A; Levesque er al., 1992), it will be of interest to see whether catecholamines elicit PKA-regulated C1current in human atrial myocytes. 8. Whole-Cell Studies
1. Regulatory Pathways a. Stirnulatory Pathway. In myocytes, p-adrenoceptor activation modulates the activity of several ion channels through the adenylyl cyclase-PKA phosphorylation pathway (reviewed by Hartzell, 1988; Gadsby, 1990). The evidence that the same pathway regulates this catecholamine-induced C1- conductance is now overwhelming and includes such facts as (1) p-adrenergic activation of this current can be mimicked by forskolin (Harvey and Hume, 1989; Matsuoka et al., 1990; Hwang et al., 1992a) or histamine (Harvey and Hume, 1990; Hwang et al., 1992a) or by intracellular application of CAMP(Bahinski et al., 1989a,b; Tareen et al., 1991,1992; Hwang et al., 1992a);(2) intrapipette application of the catalytic subunit of PKA can activate the current (Bahinski et al., 1989a; Harvey et al., 1991);(3) the C1- conductance induced by cAMP (Bahinski et al., 1989b), Is0 (Hwang et al., 1992a),or forskolin (Hwang et al., 1993a) can be completely shut down by intrapipette application of a small peptide (PKI) that specifically inhibits PKA. The PKA regulatory pathway is also influenced by the activity of the phosphodiesterases that hydrolyze CAMP. Thus, Ono er al. (1992) found that intrapipette application of cGMP enhanced the C1- conductance induced by submaximal concentrations of Iso, forskolin, or intracellular CAMP,and suggested that the cGMP might work by inhibiting phosphodiesterase, increasing intracellular [CAMP]. This idea was supported by the abolition of cGMP’s effect by milrinone, a specific inhibitor of cGMP-sensitive phosphodiesterase. Because cGMP and P-adrenoceptor stimulation have a similar synergistic action on Ca2+ current in myocytes (Ono and Trautwein, 1991),cGMP-sensitive phosphodiesterase seems to play a general role in the regulation of cellular cAMP levels.
6 . Inhibitory Pathway. Stimulation of muscarinic receptors by acetylcholine or carbachol inhibits Iso- or forskolin-induced C1- currents (Har-
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vey and Hume, 1989; Harvey et a/., 1990; Tareen e t a / . , 1991; Hwang et al., 1992a). but not C1- currents activated by pipette cAMP (Tareen et al., 1991; Hwang et al., 1992a), suggesting that the inhibition is exerted before synthesis of cAMP by adenylyl cyclase. This inhibitory effect required pipette GTP (Horie er al., 1992) and was abolished in cells incubated with pertussis toxin or in cells dialyzed with a high concentration of GDPPS, a nonspecific inhibitor of G protein turnover, demonstrating involvement of a pertussis toxin-sensitive G protein, presumably Gi (Hwang et al., 1992a). So, as previously suggested for regulation of Ltype Ca” current in guinea pig (Hescheler ef al., 1986) and frog (Fischmeister and Hartzell, 1986; Nakajima et a/., 1990; Parson et al., 1991) cardiac myoc ytes, the stimulatory 0-adrenergic and inhibitory muscarinic pathways appear to regulate the C1- current by impinging on the adenylyl cyclase via activated G, and Gi proteins, respectively. However, the precise mechanism of adenylyl cyclase inhibition by Gi seems to differ depending on whether the cyclase is stimulated by forskolin or by P-adrenoceptor activation (i.e., (3,). As demonstrated for Ca2+currents in frog myocytes (Fischmeister and Shrier, 1989; Parson et al., 19911, inhibition of forskolin-induced C1- currents by muscarinic receptor stimulation can be attenuated, and eventually overcome, by increasing the forskolin concentration (Tareen et al., 1991; Hwang et al., 1992b). In other words, the forskolin dose-response curve is simply shifted to higher forskolin concentrations by exposure to carbachol, the amplitude of the maximal response remaining unaltered; a similar effect is obtained by intrapipette application of the nonhydrolyzable GTP analogue, GTPyS, which, in the absence of agonists, preferentially activates Gi (Hwang et al., 1992a,b). In contrast to this result with forskolin, however, Hwang et at. (1992b) found little change in the apparent affinity for Is0 but a substantial reduction of the maximal response it elicited (even at 10 p M Iso) in the presence of carbachol (Hwang et al., 1992b), a result again echoing findings on frog myocyte Ca2+currents (Fischmeister and Shrier, 1989; Parson et al., 1991). These results have led to the suggestion that Gi activation reduces the potency of forskolin but reduces the efficacy of Is0 (Parson et a/., 1991; Hwang et al., 1992b), implying that Gi might interfere with the action of G , through a noncompetitive, allosteric, effect but might interfere in a competitive manner, perhaps sterically, with forskolin binding. Muscarinic inhibitory effects in guinea pig ventricular myocytes were also examined by Hescheler et al. (1986) and Tareen et a/. (1991) who studied Ca2+ and CI- currents, respectively, but both these groups reported that acetylcholine simply shifted the Is0 dose-response curves (as described above for forskolin). The apparent discrepancies between some of these reports clearly warrant further investigation. Nev-
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ertheless, the PKA-regulated C1- conductance provides a convenient monitor of cellular [CAMP]for examining the regulation of adenylyl cyclase via interactions between G,, Gi, and forskolin in an intact mammalian cell. c . Lack of Direct Coupling between G Proteins and CI- Channels. It is clear that Is0 elicits PKA-regulated CI- current through activation of the G, proteins. Thus, (i) withdrawal of GTP from pipette solutions reversibly abolished activation of the CI- current by 1 p M Is0 or by 10 p M histamine, but activation by 1 pM forskolin or by pipette cAMP remained unaffected (Horie et al., 1992); (ii) switching to pipette solution containing 1 mM GDPpS prevented CI- current activation by Is0 but not by forskolin (Hwang et al., 1992a);and (iii) with GTPyS (or GppNHp) in the pipette, a brief exposure to Is0 or histamine, but not to forskolin, caused persistent activation of the CI- current (Hwang et al., 1992a). However, the demonstration that muscarinic K + channels in atrial myocytes are opened directly by activated G, proteins (Breitwieser and Szabo, 1985; Pfaffinger et al., 1985)and evidence (reviewed by Brown and Birnbaumer, 1988)supporting direct modulation by G , of cardiac L-type Ca2+and Na’ channels, both of which are also known to be regulated through the PKA phosphorylation pathway, raise the question of a possible involvement of such a direct, mernbrane-delimited pathway in the activation of PKA-regulated CIchannels. But this has been ruled out by the observations (Hwang et al., 1992a) that (i) intrapipette application of PKI completely abolished Isoinduced CI- current with either GTP (Fig. 3) or GTPyS in the pipette, (ii) Is0 had no effect in the presence of PKI, and (iii) Is0 failed to increase CI- current activated by maximal stimulation of the PKA pathway with forskolin or intracellular cAMP (even though the current can still be increased by, e.g., phosphatase inhibition; Hwang et al., 1993a,b). Because PKI fully abolished Iso-induced CI- current even with GTPyS in the pipette, we can also rule out direct modulation of these C1- channels by any G proteins with a significant basal turnover rate, since GTPyS should have activated them all (Hwang et al., 1992a). Any influence of Gi on activation of the CI- channels other than through its effect on adenylyl cyclase (e.g., by affecting kinase or phosphatase activity) is equally unlikely, because carbachol (or acetylcholine) did not inhibit CIcurrent elicited by either maximal (Tareen et al., 1991; Hwang et al., 1992a) or submaximal (Tareen et al., 1991) levels of intracellular CAMP.
d . Infruence of External Nu+ Zons. The surprising sensitivity of the CI- current induced by P-adrenoceptor stimulation to the external “a+] (cf. Egan et al., 1987,1988)is also a consistent finding in the more recent experiments incorporating cell dialysis (Bahinski et at., 1989a; Matsuoka
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FIGURE 3 Abolition of Iso-induced CI- conductance by PKA inhibitor peptide, PKI. Chart record of current changes at 0 mV showing complete abolition of Iso- and forskolin (Fskkinduced CI- current by intracellular dialysis with PKI (A) and steady-state difference I-V relationships obtained by subtraction as indicated (B).(From Hwang et a / . , 1992a. by copyright permission of the Rockefeller University Press.)
et a / . , 1990; Harvey el a/., 1990), although its interpretation remains controversial (Harvey et a/., 1991; Tareen et al., 1992). In the first systematic study of this phenomenon, Matsuoka et al. (1990) found no response to epinephrine when Nai was replaced by TEA' or Tris+ and an apparent facilitation of the response by external cations in the sequence Na+ > K + , Rb+ > C s + ,L i + ,divalent cations. The mechanism was subsequently clarified by Tareen et a / . (1992), who concluded that the Na+ substitutes competitively inhibited P-adrenoceptor activation of G, because (i) they shifted rightward the dose-response curve for CI - conductance activation by Is0 or epinephrine, but not by histamine, forskolin, or pipette CAMP; (ii) they similarly modified Iso-induced enhancement of Ca" current; and yet (iii) the apparent affinity for Is0 activation of inward CI- current was unaffected by substitution of sucrose for external NaCI. These results
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corroborate the finding of Nagel et al. (1992)that CI- channels in excised inside-out patches could be directly activated by PKA catalytic subunit plus Mg-ATP in the complete absence of extracellular or cytoplasmic Na+ [replaced by N-methyl-D-glucamine' (NMG), or Cs'], implying that neither intra- nor extracellular Na influence C1- channel phosphorylation, gating, or permeation. In contrast, Harvey et al. (1991) reported that replacement of Nai by TMA+ (or choline, Tris+, or NMG') reduced whole-cell C1- conductance activated by Iso, forskolin, 8-Br-CAMP (membrane-permeable CAMPderivative), or IBMX or by including PKA catalytic subunit in the pipette; substitution of TMA' for Nai also diminished P-adrenoceptor-mediated stimulation of Ca2+and delayed K currents. Since Harvey et al. (19911, unlike Egan er a / . (1988)and Matsuoka et al. (1990), did not test for the influence of atropine, the inhibition of P-adrenoceptor-induced stimulation of CI- , Ca2+,and K+ currents by 140 mMTMA+ (or choline+)is presumably largely attributable to a maximal stimulation of muscarinic receptors (cf. Zakharov and Harvey, 1993); any remaining effect (cf. Zakharov and Harvey, 1993) can be accounted for by the reduced apparent affinity for P-agonists (Tareen et al., 1992). Of course, this explanation is far less satisfactory for the effects of TMA+ on CI- conductance activated by 8-Br-cAMP, IBMX, or PKA catalytic subunit. Harvey et al. (1991) also reported that TMA' replacement of Nai caused almost no diminution of forskolin-activated CI- conductance when 10 mM Na+ was included in the usually Na+-free pipette solution, or when pipette ATP was replaced by ATPyS (presumed to give rise to hydrolysis-resistant phosphoprotein), the latter finding being interpreted as suggesting that external Na+ replacement affects CI- channel phosphorylation or dephosphorylation and the former as suggesting this effect is due to a secondary depletion of intracellular Na'. However, Tareen et a/. (1992) found the same -70% reduction of Iso-activated C1- current on replacing Nai with TEA' whether the pipette solution contained 0, 15, or 115 mM Na'. Although some of the apparent discrepancies between the Harvey et af. (1991) and Tareen et af. (1992) studies remain unexplained, three results suggest some impairment of intracellular dialysis in the former. First, the difference between results with 10 mM Na+ and Na +-freepipette solutions was interpreted as indicating considerable intracellular Na+ accumulation during dialysis with Na+-free, pipette solution (Harvey et al., 1991). Second, p-adrenoceptor-mediated stimulation of membrane currents, a process known to require G protein turnover (see above), occurred in the absence of pipette GTP (Harvey et al., 1991) implying uncontrolled availability of endogenous cytoplasmic GTP. Third, cardiac PKA-phosphorylated CI channels, like overexpressed CFTR (Anderson et a/., 1991a),require hydrolyzable nucleoside triphosphate to +
+
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open (see below; Nagel et al., 1992) so that complete replacement of celluiar ATP with ATPyS would be expected to result in phosphorylated but closed CI- channels and probably ATP-lack contracture of the cell (Hwang et al., 1993a). e . Modulation of CI- Channels by Phosphatases. Deactivation of PKA-regulated C1- conductance upon removal of agonists or a switch to pipette solution containing PKI is rapid, indicating the presence of highly active endogenous protein phosphatases (Hwang et al., 1993a). Inhibition of that phosphatase activity should thus increase the steady-state level of phosphoprotein, and hence of the activated C1- conductance, and slow the subsequent deactivation of the conductance. Intrapipette application of okadaic acid or microcystin, both specific inhibitors of phosphatases 1 and 2A, causes both effects (Hwang et al., 1993a). However, even maximally effective concentrations of okadaic acid and/or microcystin fail to prevent deactivation of the CI- current upon withdrawal of forskolin, implying that phosphatase(s1 other than phosphatases 1 and 2A can also dephosphorylate the C1- channel. But, that (those) okadaic acid- or rnicrocystin-insensitive phosphatase( s) could not fully deactivate the C1conductance, and about half of it remained long after ( 2 4 0 min) washout of forskolin (Fig. 4);this residual component was insensitive to high [PKI], [CI-1 sensitive, time independent, and insensitive to stilbene derivatives. A type 1 and/or 2A phosphatase is thus required for complete dephosphorylation of these CI- channels, although partial dephosphorylation can be achieved by some other phosphatase(s). This implies two distinct forms of phosphorylated C1- channel: since the residual C1- conductance is -40-50% of the fully activated C1- conductance, the partially phosphorylated C1- channels must contribute less to the whole-cell C1- conductance than the fully phosphorylated channels. In other words, the degree of phosphorylation must regulate either the conductance or open probability of a single channel (Hwang et al., 1993a). This demonstration of the functional consequences of incremental phosphorylation is in keeping with the observation (Riordan et al., 1989) of multiple consensus sites for PKA phosphorylation in the cytoplasmic regulatory domain of CFTR and with the finding that PKA does indeed phosphorylate four or five serines in CFTR both in vivo and in v i m (Cheng et al., 1991; Picciotto er al., 1992). The okadaic acid- and microcystin-sensitive phosphatase is likely to be phosphatase 2A because preliminary results indicate that a phosphorylated inhibitor- 1 peptide, which specifically inhibits phosphatase 1, fails to affect forskolin-induced CI- current (Hwang et al., 1993b). The okadaic acidinsensitive phosphatase appears to be sensitive to orthovanadate, since
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FIGURE 4 Okadaic acid prevents complete deactivation of the Fsk-activated CI- conductance. Whole-cell current at 0 mV showing enhancement of Fsk-induced CI- conductance by okadaic acid and persistence of a CI-sensitive component after removal of Fsk (A), superimposed sample traces of difference currents from A, determined by subtracting digitized records of currents elicited by voltage pulses to +20, +40, and 560 mV under one condition from corresponding records obtained under another, as indicated (B), and steadystate whole-cell difference I-V relationships as indicated (C, D. and E). The smooth curve shows a nonlinear least-squares fit of the constant field equation to the data points. (From Hwang et nl., 1993a. by copyright permission of the Rockefeller University Press.)
its inclusion with okadaic acid in pipette solutions completely prevents any deactivation of the C1- conductance following withdrawal of forskolin (Hwang et al., 1993b). This vanadate-sensitive, okadaic acid-insensitive, phosphatase is probably phosphatase ZC, a Mg2+-dependentprotein phosphatase, because all pipette solutions contained 5:10 mM EGTA (pCa 11) and so phosphatase ZB,which is Ca*+/calmodulin-dependent, should have been completely inhibited (reviewed by Shenolikar and Nairn, 1991).
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2. Biophysical and Pharmacological Characteristics With approximately symmetrical C1- concentrations the whole-cell PKA-regulated C1- conductance is time- and voltage-independent (Bahin-
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ski et al., 1989a; Harvey and Hume, 1989; Matsuoka er al., 1990), one of the characteristics of epithelial CFTR C1- conductance. The activated currents reverse not far from estimated C1- equilibrium potentials over a range of pipette and extracellular C1- concentrations: measured reversal potentials vary roughly linearly with log,, [Cl-1, with slopes of -60 mV (Matsuoka et al., 1990) or -53 mV (Harvey et al., 1990). Shifts of the reversal potential, caused by anion substitution under nominally biionic conditions, suggest a permeability sequence of NO; > Br- > CI- z I - > F- for this Cl- channel (Overholt and Harvey, 1992; Hwang et al., 1992~).Although I - and C1- appear almost equally permeant when I- is outside and C1- is inside the cell, both the outward current at positive voltages and the inward current at negative potentials (mainly carried by C1-) are much smaller than with CI- alone (Overholt and Harvey, 1992), suggesting that I - might act as a permeant blocker of the channel (Hwang et af., 1992c; cf. Walsh and Long, 1992). Overexpressed CFTR C1- channels exhibit a similar permeability sequence (Anderson e? al., 1991b) and also seem to be blocked by I - (Tabcharani et af., 1992). Although relatively high concentrations of the stilbene derivatives, 4,4’dinitro-2,2’-stilbene disulfonic acid (DNDS) and SITS (4-acetamido-4’isothiocyanatostilbene-2,2’-disulfonate), were found to inhibit Iso-induced C1- current irreversibly under certain conditions (Bahinski et al., 1989a; Matsuoka et al., 1990; Takano and Noma, 1992),there was no effect when pipette solutions contained high [Hepes] (40 mM) and [EGTA] (50 mM) (Bahinski et af., 1989a) or when pipettes with wider tips were used to facilitate intracellular dialysis (access resistances 1-4 MR;Nagel et af., 1992; Hwang et al., 1992c), indicating that stilbenes do not block the channel itself; nor do they block epithelial CFTR CI- channels (Cliff et af., 1992). Indeed, Harvey and Hume (1991) noted that 0.1-1 mM SITS appeared to enhance Iso-activated C1- current and that SITS alone sometimes elicited C1- current, results also interpreted in terms of indirect effects on the regulatory pathway. Further preliminary tests (Hwang et ul., 1992c) on well-dialyzed guinea pig ventricular myocytes show no inhibitory effects on forskolin-induced C1- conductance of up to 2-min exposures to diphenylamine-2-carboxylic acid (DPC, 200 pM),DIDS (100 p M ) , or DNDS (0.2-1 mM). Harvey et al. (1990) found -40% inhibition of the Iso-induced C1- conductance by 100 F M anthracene-9carboxylate (9-AC) and Levesque et al. (1993) reported almost complete block by 200 pM 9-AC. Bearing in mind that P-adrenoceptor-activated whole-cell C1- conductance is regulated via a complex metabolic pathway (see Fig. 6 , below) and that these channel blockers are predominantly hydrophobic compounds capable of nonspecific effects at high concentra-
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tions, cautious interpretation of the results of pharmacological experiments seems warranted.
C. Single-Channel Current Studies
1. Cell-Attached Mode Ehara and Ishihara (1990) made the first recordings of single anion channel currents in cell-attached patches on guinea pig myocytes stimulated by epinephrine. Channels could be detected in only 4% of the patches, indicating a low density of this channel in ventricular myocyte membranes. The single-channel I-V relationship showed outward rectification, presumably largely because of the lower cytoplasmic than extracelM a r [CI-1, and a limiting slope conductance at positive potentials of -13 pS. The channels showed the slow gating kinetics characteristic of CFTR, with mean open and closed times on the order of hundreds of milliseconds and an open probability (Po)of 0.69 (SD ? 0.14; Ehara and Matsuura, 1993)which did not vary with the membrane potential (between - 120 and +60 mV). Binomial analysis of amplitude histograms of current in multichannel patches before and after recruitment of new channels, during activation by intrapipette CAMP (via a second pipette in wholecell current recording configuration), suggested that channels opened with this high Po which then remained constant for several minutes (Ehara and Matsuura, 1993): the interpretation was that PKA phosphorylation activates each CI- channel in an all-or-none manner, effectively regulating the number of active channels. Interestingly, the open probability estimated by Ehara and Matsuura (1993) is similar to the higher(corresp0nding to full phosphorylation) of two Po values observed in inside-out patch experiments (see below). It is possible that Ehara and Matsuura (1993) did not observe the lower Po mode of channel gating (see below) because of their very low cytoplasmic free [Mg2+](-lo-’ m M ) which would limit phosphatase 2C activity. 2. Excised Inside-Out Mode a. Regulation of CI- Channel by PKA and Hydrolyzable Nucleoside Triphosphates. To overcome the low channel density, the giant patch technique (Hilgemann, 1990) was used to examine activation by PKA at the single-channel level in excised inside-out patches (Nagel et a/., 1992). Once phosphorylated by PKA plus Mg-ATP, channel activity can be maintained for tens of minutes in the presence of Mg-ATP, but its removal causes prompt closure of the channel(s) (Fig. 5). Although GTP can substitute for ATP in opening phosphorylated channels, although with lower
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IW
a
L
I
b
I
FIGURE 5 Phosphorylated CI- channels in excised inside-out patches need ATP to open. (a) PKI peptide (5-24-amide) prevented channel activation by PKA plus Mg-ATP. but failed to close the phosphorylated channels after withdrawal of PKA. (b) Reversible activation of phosphorylated C1 channels by ATP. The current record begins -30 sec after the withdrawal of PKA and ATP had closed all channels: reexposure to 500 p M Mg-ATP reopened the channels. (From Nagel er d.. 1992. with permission.)
potency, neither ADP, which has no y-phosphate, nor AMP-PNP, which cannot donate its y-phosphate, can open phosphorylated channels that have been closed by withdrawal of ATP. This requirement of a hydrolyzable nucleoside triphosphate for opening PKA phosphorylated channels is believed t o be a hallmark of CFTR CI- channels (Anderson et al., 199I a). In patches containing several channels the patch current generally declines after removal of PKA, usually with a concomitant reduction of channel open time, but channel activity can be partially (or completely) restored by reapplication of PKA. The implication is that even in excised patches channels can be partially dephosphorylated by membrane-bound phosphatases and that channel activity (i.e., channel open probability) depends on the degree of phosphorylation. Consistent with this suggestion,
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patches containing a single channel occasionally show, after addition of PKA, a j u m p of Po from a relatively low value (50.3) to a higher value (20.6) despite the presence of a constant [ATP] (0.5 mM: Hwang ef ul., 1993b). These observations provide additional support for the interpretation of the residual whole-cell C1- conductance in the presence of okadaic acid (or microcystin), suggesting that partially phosphorylated C1- channels are associated with a low Pogating mode, whereas fully phosphorylated C1- channels have a high Po. According to the whole-cell data, phosphatase 2C should be responsible for the conversion from fully to partially phosphorylated C1- channels and should therefore be the membrane-bound phosphatase.
D. Summary/Synthesis of Regulatory and Gating Mechanisms
Figure 6 summarizes the metabolic pathways for modulation of PKAregulated CI- channels in cardiac myocytes. Agonist stimulation of receptors regulates adenylyl cyclase activity through stimulatory or inhibitory G proteins. The intracellular cAMP level that results from cyclase and phosphodiesterase activity determines the level of protein kinase A activaForskolin
M2 Muscarinic
c1
FIGURE 6 Schematic representation of the regulatory pathways of cardiac PKAactivated CI- channels. Various hormonal receptors regulate the CFTR CI- channel by impinging on the adenylyl cyclase through G proteins, and the resulting alteration of intracellular cAMP levels modulates PKA, which directly phosphorylates the channel molecule. At least two PKA phosphorylation sites can be differentiated by their different sensitivity to protein phosphatases and their different contribution to whole-cell CI- conductance (see text and Fig. 7).
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tion. which in turn controls the rate of phosphorylation of C1- channel molecules. The dual phosphorylation model in Fig. 7 can account for all present results obtained both in whole cells and in excised membrane patches. Complete dephosphorylation of the channel requires phosphatase 2A and a second, vanadate-sensitive, phosphatase, likely phosphatase 2C. Because it is known that PKA-phosphorylated CFTR C1- channels are gated by Mg-ATP, it will be important to learn whether, and if so how, ATP control of channel gating differs depending on the degree of channel phosphorylation. E. Functional Role and Cardiological Significance
Documentation of the molecular identity of the cardiac PKA-regulated C1- channel and elucidation of its regulatory mechanisms have preceded a clear understanding of its functional role in the normal human ventricle, let alone the potential pathophysiological impact of its absence or dysfunction in patients with cystic fibrosis. Upon P-adrenoceptor stimulation the normally steep CI- ion gradient is expected to drive a substantial outward, repolarizing, current through these channels during the plateau of the cardiac action potential. This outward current should counteract the influence of the simultaneously enhanced Ca2+current to prolong the action potential duration, and, at the same time, it should increase Ca2+ entry into the cells during the action potential plateau by holding the membrane potential away from the Ca2+ equilibrium potential. In support of this suggestion, Harvey et al. (1990) demonstrated that activation of the C1current did shorten the action potential duration, but the measurements
FIGURE 7 Suggested phosphorylation scheme for the CFTR Cl- channel. PKA activates the inactive channel by phosphorylating the P, site, while additional phosphorylation of the P2 site, to yield PIP,, increases the open probability of the active channel opened by ATP. Preliminary results suggest that channel molecules with only the P2site phosphorylated are likely to be nonconducting.
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were made at room temperature to prevent simultaneous activation of delayed rectifier K + channels so that the relative contributions of these two current components to the shape of the action potential remains unclear. Measurements using 200 p M 9-AC to abolish the C1- current also demonstrated its ability to shorten action potential duration, but again precluded direct comparison of the relative roles of K t and C1- currents (Levesque et ul., 1993).On the other hand, Takano and Noma (1992) used the nystatin-perforated patch technique on rabbit ventricular myocytes, at 36“C, and found that whereas 0.3 pM Is0 caused a slight reduction of the action potential duration (on average), subsequent exposure to 1 mM DNDS caused a marked prolongation. Because, in the same cells, DNDS did not alter action potential duration in the absence of Iso, implying lack of effect on Ca2+or K’ current, the conclusion was that (i) DNDS prolonged the action potential in Is0 by inhibiting PKA-regulated C1current and, hence, (ii) that this current does normally counter the tendency of the enhanced Ca2+current to increase action potential duration (Takano and Noma, 1992). (As already mentioned, this effect of DNDS in poorly dialyzed myocytes is presumably not due to direct block of the C1- channel, but to some indirect effect on its regulation.) Unopposed lengthening of the action potential duration by Ca’+ current enhancement could excessively prolong the refractory period, predisposing the heart to arrhythmias, as in the long Q-T syndrome (Vincent et al., 1974). Despite the sparse electrocardiological literature on C F patients, ventricular dysfunction during stress (Benson et al., 1984)and arrhythmias (Cheron et al., 1984; Sullivan et al., 1986) have been reported, but are usually assumed to be consequences of the pulmonary dysfunction (cor pulmonale) often associated with CF. However, if systematic electrocardiographic studies were to reveal ventricular repolarization abnormalities in CF patients, then a lack of PKA-dependent stimulation of cardiac C1- channels, but not of Ca2+ channels, would provide a reasonable explanation. Several kinds of studies are now warranted to address the question of the functional role of CFTR in human hearts. First, Northern analysis of atrial (Levesque et uf., 1992) and ventricular tissue should establish whether there are regional differences in the level of CFTR expression within the human heart. Second, electrophysiological studies of atrial and ventricular myocytes from normal and CF hearts should establish patterns of function of CFTR in those hearts. And finally, electrocardiographic measurements, with and without sympathetic stress, should be compared for normal hearts, for CF patients, for CF patients with lung transplants, for CF patients with heart and lung transplants, and for nonCF patients who have received CF hearts in “domino” transplant operations; such a systematic set of measurements should shed light both on
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the normal role of these CI- channels and on the pathophysiological significance of their possible dysfunction in C F patients. On the other hand, since one result of the enhanced C1- current is a facilitation of Ca2+ entry (above), the postulated failure of these channels in CF patients might afford them some degree of protection against the possibly dangerous consequences of excessive Ca2+ entry. Another, related, suggestion (Levesque et al., 1993) is that the abbreviated action potential resulting from C1- current activation might be considered dangerous and that agents that diminish the CI- current, and so prolong the action potential, might have antiarrhythmic properties (like the Class I11 antiarrhythmics that inhibit K + channels). In this view, again, possible dysfunction of cardiac C1- channels in C F patients could be considered beneficial. It is even conceivable that a mechanism like one of these could contribute to the selection pressure that has managed to keep CF mutations so prevalent in the Caucasian population. A careful analysis of appropriately recorded and selected electrocardiograms should begin to shed light on these kinds of questions. II I. STRETCH-ACTIVATED CI - CHANNELS
Stretch-activated ion channels have been found in a wide variety of cell types and are thought to play an important role in the regulation of cell volume (see review by Morris, 1990). A C1- current activated by the membrane stretch associated with cell swelling has been identified in cardiac myocytes isolated from rabbit atria and SA node (Hagiwara et al., 1992a,b), dog atria (Sorota, 1992) and ventricles (Tseng, 1992), and cultured embryonic chick heart (Zhang et al., 1992). This C1- current can be elicited by hypertonic internal (Tseng, 1992) or hypotonic external solutions (Hagiwara et al., 1992a; Tseng, 1992; Sorota, 1992; Zhang et al., 1992), by direct mechanical inflation of the cell (Hagiwara et al., 1992b), or by exposing ventricular myocytes to anion amphipaths, such as dipyridamole or 2,4,6-trinitrophenol, which are believed to preferentially insert into the outer leaflet of the membrane and so cause a distortion of the membrane comparable to that occurring during cell swelling (Tseng, 1992). Since induction of this stretch-activated C1- current was found to be affected by neither a specific PKA inhibitor nor the nonspecific kinase inhibitor, H7, it seems unlikely that phosphorylation is involved in the regulatory mechanism (Hagiwara et al., 1992b). Nor is it likely that intracellular Ca2+ions are important for its activation because of the high [EGTA] (e.g., 10 mM; Hagiwara et al., 1992b)generally included in pipette solutions and because cell swelling can elicit the
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current in myocytes simultaneously exposed to Ca2+-freeexternal solutions containing ryanodine (to prevent Ca2+release from the sarcoplasmic reticulum) and dialyzed with EGTA-containing pipette solutions (S. Sorota, personal communication). Preliminary reports of single anion channel currents elicited by osmotic swelling demonstrate (i) in the cell-attached patches on chick myocytes, a strong outwardly rectifying I-V relationship and a single-channel conductance of 31 pS at 0 mV (Zhang et al., 1992) and (ii) in inside-out patches excised from rabbit atrial myocytes, a single-channel conductance of 35 pS in symmetrical 150 mM [Cl-] solutions (Hagiwara et al., 1992a). Estimation of the anion selectivity from reversal potential shifts in wholecell experiments gave a permeability sequence of I- > NO,- > Br- > C1- > F- (Hagiwara et al., 1992b). And, this current can be reduced by some C1- channel blocking agents, including DNDS (1-5 mM), SITS ( I mM) (Hagiwara et al., 1992b), 9-AC (1 mM; Hagiwara et al., 1992b; Tseng, 1992; Sorota, 1992),niflumic acid (100 pM; Sorota, 1993), indanyloxyacetate (100 pM; Sorota, 19931, and nitrophenylpropylamino benzoate (NPPB, 40 pM; Tseng, 1992). Like that of PKA-regulated C1- channels, the function of this stretchactivated C1- channel remains speculative, although, by permitting efflux of C1-ions together with K+ ions, it could be involved in a regulatory volume decrease in response to swelling of cardiac myocytes. Activity of the channel could become important, for example, during the cardiac cell swelling known to accompany cardiac ischemia and reperfusion (TranumJensen et al., 1981).
N. Ca2+-ACTIVATED CI- CHANNELS Early studies on cardiac Purkinje fibers by Kenyon and Gibbons (1979) showed that the transient outward current induced by step depolarization to positive potentials included two components: a K+ current sensitive to 4-aminopyridine (4-AP) and a chloride-sensitive but 4-AP-insensitive component. From patch-clamp studies on rabbit ventricular and atrial myocytes the charge carrier for this latter component was concluded to be C1- ions, because the 4-AP-insensitive transient current disappeared upon reduction of the external [Cl-] sufficient to make the C1- equilibrium potential equal to the pulse potential (Zygmunt and Gibbons, 1991), and reversal potentials of quasi-instantaneous I-V relations, determined with double-pulse protocols, shifted with the C1- equilibrium potential when [Cl-I, was altered (Zygmunt and Gibbons, 1992).
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The Ca’+-dependent nature of this current was based on the observations that the current appeared only when the intracellular Ca2+buffering was low (pCa = 7.7 or 8.3 with 0.2 or 0.8 mM EGTA) and that it was abolished by 10 mM intracellular EGTA or by inhibition of voltageactivated, L-type Ca2+ current with Cd2+ or nisoldipine (Zygmunt and Gibbons, 1991). Interestingly, this C1- current was also abolished by ryanodine or caffeine, both of which prevent sarcoplasmic reticulum Ca2+ release, indicating that the underlying C1- channels are activated by the Ca’+ ions that are released from the sarcoplasmic reticulum rather than by the trigger Ca2+ions that enter through L-type CaZt channels (Zygmunt and Gibbons, 1991,1992). The Ca2+-activated CI- current was larger in atrial than in ventricular cells, but it is not yet clear whether this reflects a difference in channel density or in factors influencing the localized intracellular [Ca”] near the channels. So far, only preliminary single-channel data are available (Zygmunt and Gibbons, 1993); the on-cell single-channel conductance was reported to be 43 pS for outward current and 18 pS for inward current, not very different from the conductance of C1- channels activated by swelling in the same cells (Hagiwara et al., 1992a) or even in cultured chick heart cells (Zhang et al., 1992). The Ca’+-activated whole-cell CI- current was consistently found to be abolished by 0.1 mM DIDS or 2 mM SITS (Zygmunt and Gibbons, 1991,1992).Although the Ca’+-sensitive C1- channel is evidently distinct from the PKA-regulated C1- channel, it is not at all clear that it is distinct from either the stretch-activated CI- channel or C1- channels suggested to be activated by protein kinase C (Walsh, 1991; Zhang and Ten Eick, 1993). Because of its transient nature, by virtue of its dependence on the brief, large rise in intracellular [Ca”], this C1- current is likely to contribute to whole-cell membrane conductance only early during the cardiac action potential. Together with the larger, 4-AP-sensitive, transient K+ current, it probably contributes to the rapid phase 1 repolarization of the atrial action potential; indeed, Takano and Noma (1992) noted that application of I mM DNDS blunted that early repolarization phase in rabbit atrial myocytes, but had a much smaller (if any) effect on the far less extensive phase 1 repolarization of ventricular myocytes. V. OTHER CI- CHANNELS
Walsh (1991) reported activation of a time-independent C1- conductance in guinea pig ventricular myocytes, at room temperature, by external
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application of the phorbol ester, PMA, or of norepinephrine in the presence of propranolol ( to stimulate a-adrenoceptors) or by dialyzing the cell with partially purified protein kinase C. The whole-cell I-V relationships were described as approximately linear despite asymmetrical [CI-1 and were shifted in a parallel fashion by lowering [Cl-I,. This PMA-activated current was reduced to about half by exposure to the monocarboxylic acid derivative, 8-chlorophenoxypropionic acid (CPPA). More recently, Zhang and Ten Eick (1993) described activation by PMA in feline ventricular myocytes of a time-independent C1- conductance that was sensitive to 9-AC. Maximally effective concentrations of PMA precluded activation of PKAregulated CI- conductance by forskolin, but the effects of submaximally activating concentrations of PMA and forskolin seemed additive, leading to the suggestion that the same population of C1- channels subserves the C1- conductance activated by both signaling pathways. It will be interesting to see whether similar effects can be demonstrated in excised membrane patches by direct application of PKC and/or PKA. Extracellular ATP, its nonhydrolyzable analogue ATPyS, ADP, AMP, and adenosine were all found to activate a C1- current in guinea pig atrial myocytes (Matsuura and Ehara, 1992; cf. Scamps and Vassort, 19901, but the subtype of the purinergic receptor involved and the detailed mechanism of channel activation are not yet clear. In addition to the electrophysiological characterization of CI- currents described above, molecular expression studies of mRNA injected into Xenopus oocytes have begun to contribute to our understanding of the full spectrum of cardiac C1- channels. Thus, Jentsch and colleagues have already identified three C1- channel homologs: ClC-0, the voltagedependent C1- channel cloned from the electric organ of Torpedo marrnoruta (Jentsch et ul., 1990); CIC-1, the principal C1- channel of skeletal muscle (Steinmeyer et ul., 1991); and CIC-2, a C1- channel activated by hyperpolarization (Thiemann et al., 1992) and probably by cell swelling (Griinder et al., 1992) that appears to be ubiquitously expressed in, for example, heart, brain, pancreas, lung, and liver. Although oocytes injected with mRNA transcribed from CIC-2 generated a C1- conductance that was activated by strong hyperpolarization (to between -100 and -180 mV) and that could be partially blocked by 1 mM DPC or 1 mM 9-AC, an equivalent current has not yet been demonstrated in cardiac myocytes, probably because of the large negative voltages required to open the channels (Thiemann et al., 1992). Another, quite different, suspected C1- channel clone has been isolated from rat heart (Paulmichl et al., 1992). When expressed in oocytes, it induced a CI- current that could be diminished not only by DIDS (50% inhibition at 20 p M ) and NPPB (2 p M ) but, surprisingly, also by extracel-
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lular CAMP.The primary structure (235 amino acids) of this clone suggests no a-helical membrane-spanning segments, but is consistent with a pbarrel structure spanning the membrane of the kind shown for porin channels (Weiss et a / . , 1991; cf. Blachly-Dyson et al., 1990). Expression has been demonstrated in rat atria and ventricle, but it has yet to be seen whether this C1- channel is present in the sarcolemrnal membrane. Finally, the least-characterized putative cardiac Cl- channel, a 72-amino acid sarcolemmal protein called phospholemman, is the major cardiac substrate for phosphorylation by PKA and PKC. Its expression in Xenopus oocytes is associated with the appearance of a h yperpolarization-activated CI- current sensitive to 9-AC (Moorman et d., 19921, a characteristic shared by the expression product of CIC-2. But it is not yet clear whether phospholemman itself forms a Cl- channel o r modulates preexisting covert CI- channels.
VI. SUMMARY
AND OUTLOOK
The application of patch-clamp techniques to cardiac myocytes has provided convincing evidence for the existence of at least three kinds of cardiac C1- channel. The differences in their regulatory mechanisms suggest that each might play adistinct role in modulating the resting membrane potential or the action potential of myocytes according to the circumstances, depending, for example, on whether there are circulating catecholamines or there is cell swelling or release of Ca?' from the sarcoplasmic reticulum. Because the equilibrium potential for Cl- ions in heart cells normally lies between -65 and -45 mV (Vaughan-Jones, 19821, opening of C1- channels at ventricular diastolic membrane potentials will tend to cause C1- efflux and hence membrane depolarization, whereas C1- channel opening during the action potential plateau will shorten its duration due to a repolarizing CI- influx. Indeed, shortening of the action potential duration as a result of activation of PKA-regulated C1- channels has been established (Takano and Noma, 1992; cf. Harvey et a/., 1990; Levesque et a/., 1993). Correspondingly, adrenergic agonists have been reported to cause a small variable depolarization of ventricular cells during diastole (Harvey et a/., 1990; Matsuoka e t a / . , 1990; but cf. Sorota et a/., 1991) which became marked when the intracellular C1- concentration was artificially elevated (Harvey et al., 1990; Sorota et a/., 1991; Yamawake et a / . , 1992).However, thorough examination of the significance of effects like these has been hindered by the lack of specific blockers for any of the cardiac C1- channels, leading to difficulty in evaluating the contributions of changes in C1- current relative to those of other currents.
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As demonstrated with great success for cation (notably K + ion) channels, the appropriate combination of molecular biological and electrophysiological tools should eventually allow us to understand the relationship between the structure and function of individual CI- channels. Thus, although the CFTR protein is now known to be responsible for PKAregulated cardiac C1- currents, further work will be required to shed equivalent light on the molecular identities of the other cardiac C1- channels. Even more work, of a different kind, including clinical studies, will be needed before we understand the physiological roles of each of the cardiac C1- channels and the potential pathophysiological consequences of their dysfunction, for example, in patients with cystic fibrosis.
Acknowledgments The preparation of this review and our research summarized in it were supported by NIH HL-14899 and HL-49907 and the American Heart Association New York City Affiliate. We thank Peter Hoff for invaluable technical assistance.
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Index A
Acetylcholine, muscarinic receptor stimulation, 324-325 Acid-base transport. connecting tubule of distal nephron, 283-284 Action potentials and arrhythmias. 336 in giant algal cells. 2 in guard cells. origins. 5 Adenosine chloride current regulation. 292 tubuloglomerular feedback system. 269-272 Adenosine triphobphate. sm ATP Adenylyl cyclase G , effects, 325 PKA-regulated chloride channel effects. 32 1-323 Alcohol. effects on GABA, receptors, 235-236 Alcoholism, and GABA receptors, 243-244 Algal cells, giant action potentials. calcium and ATPmodulated anion conductance, I I plasma membrane, action potential. 2 y-Aminobutyric acid receptors, see GABA receptors Angelman’s syndrome. GABA, receptor subunit genes and. 219-222 Anion channels in guard cells auxin effects. 12-14 malate effects, 15 single-channel conductance, 8-9 plant, diversity. 19-23 putative protein. identification. 12 VDAC. 76 voltage dependence categories, 19 volume excitation. 23
Anions conductance. calcium dependent. action potential activation. 2 extracellular. single-channel conductance and activation kinetics, 8-9 selectivity sequence, CFTR chloride currents, 157 Apical membranes chloride conductance. in chloride secretion, 187 cystic fibrosis transmembrane conductance regulator location. I55 epithelial cell. p64 targeting, 70-71 Gt.7 expression. 195-196 proximal nephron tubules, chloride conductance. 277 transepithelial chloride current flow, 177 Arrhythmias. and action potential duration increases. 336 ATP. hydrolysis and cystic fibrosis transmembrane conductance regulator, 183 nucleotide-dependent regulators, 165 Auxins. stomata1 aperture effects, 12-13
B Barbiturates. GABA, receptor effects, 233 Basolateral membranes macula dense cells. chloride conductance measurements. 268-269 proximal nephron tubules chloride transport, 275 swelling-activated chloride channel, 276 Benzodiazepines. GABA, receptor effects. 232-233 Brain. GABA, receptor subunits, 217-219 341
Index C
Calcium cytoplasmic, ionic current polarization. 22-23 cytosolic. midi chloi-ide channel regulation. 1 15 GCACl effects. I I mitogen-stimulated signaling. in Jurkat T cells. 106-107 Carbon dioxide. stomata1 aperture effects. 14-15 Cardiac myocytes. see t h o Heart action potential modulation. chloride channel effects. 341 chloride conductance. types. 318-319 ion channels modulation, p-adrenoceptoi effects. 324-325 PKA-regulated chloride channel modulation, metabolic pathways. 334-335 Catecholamines. PKA-regulated chloride channels and. 323 Cell5 action potential repolarization, 318 epicardial. action potential duration, 323-324 epithelial apical membrane. p64 location. 70 salt-secretory, cellular mechanisms, 17% I76 intercalated, chloride reabsorption, 289-290 mini chloride channels. volume regulation. 122- I23 Central nervous system, GABA, receptor distribution, 237-238 CFTR, .see Cystic fibrosis transmembrane conductance regulator Chloride channels biochemical and pharmacological characteristics. 330-332 calcium-activated, lymphocytes. 106 CFTR biophysical properties, 157-158 nucleotide-dependent regulation. 163-1 66 phosphorylation-dependent regulation, 160-162 topology and localization, 155-156
in eukaryotic cells. purpose. 59 fast, skeletal muscle, 132 depolarization effects. 142 tetraethylammonium ion effects, 148 voltage dependence. 140-144 and G proteins. relationship, 326 homologs CIC-0. 38. 340 CIC-I. 41. 43 CIC-2, 45. I13 1AA-sensitive and p64. 64 purification and reconstitution, 62-63 imaging. electron microscopy, 84-89 kidney-specific, CIC-KI and CIC-K2. 47 in lymphocytes midi-CI- channel. 113-1 17 mini-CI- channel, 108-1 13 resting potential. 120-121 maxi. S P C Maxi chloride channels midi. scr Midi chloride channels mini. see Mini chloride channels nephron. 265-267 neuronal. permeability properties. 144-146 organelles, intracellular, 297-298 PKA-regulated. see PKA-regulated chloride channels plasma membrane. 60-61 putative protein, identification, 12 renal biochemistry, 299-301 salt secretion, cellular mechanisms, 174- 175 slow. skeletal muscle. 132 stretch-activated. function, 337-338 time-independent, 339-340 voltage-gated CIC-0, 36-40 molecular characteristics, 35 Xcnopits oocyte studies, 38-40 Chloride conductance Gel. in transepithelial salt transport, 174 G C P , sre GcAMPCl ($7. chemical origins. 197-198 Chloride transport inner medullary collecting duct. 292-293 juxtaglomerular apparatus, 267-272 Madin-Darby canine kidney cell line studies, 296-297
Index outer medullary collecting duct. 293-295 Xcnopiis kidney cell line A6. 295-296 CIC-0. ion selectivity measurements. 38 CIC- I cloning. 43 muscle locations. 41 CIC-2 and mini chloride channels. 113 muscle location. 45 Complementary DNA CIC-2, 44-4s cystic fibrosis transmembrane conductance regulator. 156 p64 cloning. 65-69 Torpedo n~~irmiirfitci, 37 Conditional distributions. CI channels in skeletal muscle composition. 136- I37 single-channel kinetic studies. 138 Connecting tubule. chloride transport. 283-284 Convoluted tubule. distal. sec Distal convoluted tubule Cortical collecting duct chloride channels, patch-clamp studies, 288 composition. 287 intercalated cells. chloride conductance, 289-290 Cystic fibrosis atrial and ventricular myocytes in, electrophysiological studies. 336-337 and chloride channels. 61-62 GE:MP effects, 196 gCl regulation, calcium importance. I16 p64 role, 62 transepithelial salt transport, 174 Cystic fibrosis transmembrane conductance regulator ATP binding and channel gating. 183-184 chloride channel activation by cellular cAMP increase, I82 ADP effects, 165-166 biophysical properties, 156-159 PKA-regulated. 321 composition. 153-154 conductive properties, amino acids mutation. 159
midi chloride channel regulation. 117 phosphorylation. functional consequences. 162 regulation, R-domain phosphorylation role. 160-163 topology and localization, 155-156
D Deactivation. GCACI in guard cells, 10 Depolarization calcium influx effects. 122-123 fast chloride channel effects. 142 mesangial cells, 273-274 Desensitization, GABA, receptors, molecular mechanisms. 229-230 Diseases alcoholism. GABA receptor role. 243-244 cystic fibrosis. and chloride channels. 61-62 epilepsy. GABA receptor role. 243 hepatic encephalopathy. GABA receptor role. 244 myotonia. human. chloride conductance role. 43-44 Distal convoluted tubule. chloride transport, 282-283 Distribution analysis, two-dimensional, single-channel kinetics studies, 140 DNA. complementary, see Complementary DNA Downregulation, GABA, receptors. 230-23 1
E Electrodes. see Microelectrode studies Electron microscopy, chloride channel imaging, 84-89 Encephalopathy, hepatic, GABA receptor involvement. 244 Endocytosis, cAMP regulation. 186 Epicardial cells, action potential duration, 323-324 Epilepsy. GABA receptor role, 243 Epithelial cells apical membranes, p64 targeting, 70-71
Index salt-secretory apical membrane chloride conductance mechanisms, 186 cellular mechanisms, 175-176 CFTR location. 185 (3%. occurrence and location, 194-195 secretagogue-activated chloride conductances, 178-179 transmembrane salt transport. Gc,, 176 whole-cell current. properties, 198-200 Excitability, in skeletal muscles, slow and fast chloride channel effects, 132 Exocytosis. CAMP regulation, 186
F Forskolin activation of catecholamine-induced chloride conductance, 324 adenylyl cyclase inhibition, 325
G GABA receptors composition, 60 and glycine receptors, comparison, 244-245 GABAA receptors agonists and antagonists, 231 alcohol effects, 235-236 benzodiazepine and barbiturate effects, 232-233 desensitization, 229-230 distribution central nervous system, 237-238 developmental changes, 240-241 glial cells, 239 invertebrates, 241-242 outside nervous system, 239-240 peripheral nervous system, 238 downregulation, 230-23 I function, 226-230 native. composition, 223-224 subunit multiplicity, 217-219 Gating modifiers, types, 12-17 GCACl and anion channel blockers, characteristics, 17 auxin interaction, 13-14
calcium effects, I I excitability. voltage dependence and kinetics influence, 25-26 nucleotide effects, I I patch-clamp studies, anion channel identification and selectivity, 6-7 GM :; P
macroscopic whole-cell current, properties, 179- 180 occurrence and cellular location, 185- 186 regulation, 187-1 88. 193-1 94 single-channel basis, 181- 182. 191-192 Gel. in transepithelial salt transport, 174 Glial cells. GABA, receptors, 239 Glomerular hemodynamics. mesangial role, 273 Glycine receptors, and GABA receptors, comparison, 244-245 Golgi membranes, see also Organelles. intracellular cystic fibrosis, 61-62 G proteins, and chloride channels, relationship, 326 G proteins, G, adenylyl cyclase inhibition, 325 P-adrenoceptor activation, sodium inhibitory effects, 327-328 Growth hormones, involvement in voltage dependent anion channels, 12-13 Guard cell anion channel, see GCACl Guard cells anions, extracellular activation kinetics, voltage dependence, 9-1 1 role in single-channel conductance, 8-9 auxin signaling, 12 ion transport, plasma membrane, 3 voltage sensor alterations anion channel blockers, 15-17 extracellular growth hormones, 12-13 malate, 15 GvO1 C I , chemical origins, 197-198
H Heart, see also Cardiac myocytes PKA-regulated chloride channel effects, 321-324. 335-337
351
Index Henle's Loop. descending and ascending limbs. chloride transport. 279-281 Hepatic encephalopathy. GABA receptor role, 244 Hypertonicity. mesangial cells. chloride transport. 272 Hypotonicity. CIC-2 activation, 45
I IAA-sensitive chloride channel and p64. 64 purification and reconstitution, 62-63 Imaging techniques. chloride channels, freeze techniques. 86-88 Immunoprecipitation. native GABA, receptor isolation. 225-226 Intercalated cells. cortical collecting duct, in chloride transport. 289-290 Invertebrates. GABA receptors. 241-242 Ion channels. ligand-gated GABA, receptors, 217 receptor function modulation. phosphorylation, 223 Ion transport guard cell. basic function, 5 and stomata1 aperture. 3-5
J Jurkat T cells, mitogen-stimulated calcium signaling, role of Ca2+and K + channels, 106- 107 Juxtaglomerular apparatus, macula dense cells. chloride transport. 267-272
K Kidney. see also Madin-Darby canine kidney cells; Xenopus kidney cell line collecting tubule, chloride transport. 283-284 cortical collecting ducts chloride channels, 288 composition. 287 intercalated cells, 289-290 distal convoluted tubule. chloride transport. 282-283
Henle's Loop. descending and ascending limbs. 279-281 ion transport. cultured cell models, chloride transport in. 295-297 juxtaglomerular apparatus. macula dense cells. 267-272 proximal tubule. chloride transport. 274-278 Kinetics GCAC I . and excitability. 25 single-channel studies, 135-136 neuronal chloride channels. 146
L Lymphocytes, see nlso Jurkat T cells chloride channels midi-CI- channel. 113-1 17 mini-CI- channel. I10 resting potential. 120-121 ion channel phenotype, 104-107
M Macula dense cells. chloride conductance, intracellular microelectrode techniques, 268-269 Madin-Darby canine kidney cells chloride currents. 47 chloride transport studies, 296-297 Magnesium, and ATP hydrolysis. 165 Malate. role in guard cell C 0 2 regulation, 14-15 Mast cells, small chloride channel. comparison with lymphocyte rnini-CIchannel, 112 Maxi chloride channels opening factors. 123 properties, 117-120 Medullary collecting ducts. inner and outer. chloride transport, 292-295 Membranes. phospholipid. VDAC properties, 75-76 Mesangial cells, chloride transport, 272-274 Metabolites. in mitochondria, VDAC channel importance, 96 Microelectrode studies guard cell ion transport, 5
352
Index
intracellular. intercalated cell chloride channels, 291 transepithelial chloride current flow, major limitations. 178 Midi chloride channels kinase-regulated conductance, imaging versus patchclamp studies. I16 properties. 113-1 17 opening factors, 123 Mini chloride channels CIC-2 gene. 113 comparison with other channels, 110-1 I I opening factors. 123 Mitochondria, VDAC. 74 properties. 80-82 Mitogenesis. site-directed, in lymphocytes, chloride channel effects. 121-122 Molecular biology. and renal chloride channel biochemistry, 299-30 I Muscarinic receptors. stimulation. acetylcholine effects. 324-325 Muscles. skeletal chloride channel CIC-I. 42 slow and fast chloride channels, 132 Mutagenesis. site-directed GABAA receptor agonist studies. 231-232 I,,, studies, 48-49 VDAC membrane channel closure analysis, 90 Mutations, recessive, 44 Myocytes. cardiac action potential modulation, chloride channel effects, 341 chloride conductance, types, 318-319 ion channel modulation, P-adrenoceptor effects. 324-325 PKA-regulated chloride channel modulation. metabolic pathways, 334-335 Myotonia animal models, CIC-I effects, 42-43 human. chloride conductance role. 43-44
N NBD. see Nucleotide-dependent regulators Nephron chloride transport, 265-267
distal convoluted tubule. chloride transport. 282-283 juxtaglomerular apparatus, chloride transport in macula dense cells, 267-272 proximal, chloride transport. 274-278 Neurons. chloride-selective ion channels. 144-148 quaternary ammonium ion blockade. 148 Nonhematopoietic cells. mini chloride channels. I 11-1 12 Nucleotide-dependent regulators, in CFTR chloride channels. ATP hydrolysis role. 163
0 Oocytes. Xenoprts chloride current activation. phospholemman. 49 chloride current studies. 340 CIC-0 characteristics. 38 CIC-2 activation. 45 phospholemman studies, 341 P ~ C I 48 ~. recombinant GABAA receptor studies. 226 renal chloride channel studies, 299 Open and closed states, VDAC, osmotic pressure effects. 92-93 Organelles, intracellular, see ufso Golgi membranes chloride channels, 59-60, 297-298 Osmotic pressure. colloidal, VDAC effects, 92-93 Outward rectifier apical chloride conductance, 204 properties, 202-203
P P64 cDNA cloning, 65-69 and cystic fibrosis. 62 epithelial cell location, 70-71 as IAA-sensitive chloride channel component, 64 as vacuolar chloride channel, 60-61
l n d ex Patch-clamp studies cardiac myocytes. 341 chloride channels midi-CI- channel conductance. 116 mini-CI channel properties. 108-1 13 CIC-0. in Xenoprrs. oocytes. 40 cortical collecting duct. chloride channels, 288-289 GCACI anion channel identification and selectivity, 6-7 guard cell ion transport. 5 ion channel phenotypes. in lymphocytes. 104- I07 ion channels, 2-3 proximal nephron tubules apical membrane chloride conductance. 277-278 basolateral chloride conductance, 276 transepithelial chloride current flow. 178 Phosphatases. modulation of chloride channels in heart, 329-330 Phospholemman chloride channel. 36 muscle origins. 49-50 PKA phosphorylation. 341 Phospholipid membranes, VDAC properties, 75 Phosphorylation CAMP-dependent. CFTR regulation, 154 CFTR. functional consequences. 162 ligand-gated ion channels, 223 PKA-regulated chloride channels. 329-330 plcln.chloride channel potential. 48-49 PKA-regulated chloride channels biophysical and pharmacological characteristics, 330-33 I composition. 319-321 conductance levels, G , activation, 326 phosphatase modulation, 329 physiological role. 323 regulation. hydrolyzable nucleoside triphosphates. 332-334 Plants. anion channels. 19-23 Polyanions. VDAC voltage dependence effects. 93-94 Potassium anion channel permeability to, 23-24 Potassium channel blocker. quaternary ammonium ions, CI- channel blockade. 146-147
353 Potassium channels in mitogen-stimulated Ca’+ signaling in T cells. 106 voltage-gated. in lymphocytes. 105 Principal cells. cortical collecting duct. chloride channels. 289 Protein kinase A. regulated chloride channels. see PKA-regulated chloride channels Protein kinase C, in chloride secretion in salt-secretory epithelial cells. 187-188 Protein kinase G. CFTR as phosphorylation substrate, 188 Proximal nephron. chloride transport in proximal tubule, 274-278 Proximal tubule. renal. chloride transport. 274-278
Q Quaternary ammonium ions, chloride channel blockade. 146-147
R R-domain. CFTR regulation. 160-163 Regulators, nucleotide-dependent, CFTR chloride channels. ATP hydrolysis role, 163 Restriction fragment length polymorphisms. in linking CIC-I to myotonia, 43 RNA. alternative splicing, in GABA, receptor multiplicity. 222-223
S Sarcoplasmic reticulum, calcium-activated chloride channels. 339 Single-channel studies, PKA-regulated chloride channels, cell-attached mode, 332 Skeletal muscle chloride channel, CIC-I. 42 slow and fast chloride channels, 132 Sodium ions. external. in cardiac chloride channel regulation. 326-329
Index
354 Stomata1 aperture auxin effects, 12-13 COz effects. 14-15 ion transport, 3-5 Stretch-activated chloride channels. function. 337-338 Swelling, chloride conductance activation, 197-201
T T cells. Jurkat. see Jurkat T cells Tetraethylammonium ion. potassium channel blockade. 146-147 Thapsigargin. in study of Ca" dependence of cellular gene expression, 122 Torpedo mrrrrnorrittr cDNA. 37 CIC-0 locations, 40 voltage-gated chloride channel studies. 36-40 Tubuloglomerular feedback, 265 and adenosine. 269-272
U Unconditional distributions, chloride channels in skeletal muscle, 136
V
VDAC. see Voltage-dependent anionselective channels Voltage dependence anion channel types. 19 fast chloride channel kinetics, 140-144 voltage-dependent anion-selective channel, influencing properties. 92-95 Voltage-dependent anion-selective channels imaging techniques. open and closed state structure, 89
and large-conductance chloride channels, comparison, 142 modulator effects. 93 molecular structure composition. 76-78 from electron microscopic imaging. 84-89 open state. 82-84 pore size. 78-80 secondary. 80-82 open and closed states. osmotic pressure effects. 92-93 properties. 74-75 voltage gating effects, pore size reduction. 90-91 Voltage gating. membrane channels defined. 90 maxi chloride channel. 119 VDAC. characteristics, 90-91
W
Whole-cell studies. PKA-regulated chloride channels conductance pathways, 321 regulatory pathways. 324-326
X Xenopus. oocytes chloride current activation. phospholemman. 49 chloride current studies, 340 CIC-0 characteristics, 38 CIC-I. chloride currents. 41 CIC-2 activation. 45 patch-clamp studies. 40 phospholemman studies. 341 PlCI". 48 recombinant GABA, receptor studies, 226 renal chloride channel studies, 299 Xmoprts kidney cell line. chloride transport, 295-296
ISBN 0-32-L53342-5
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